CN113020830A

CN113020830A - Splicing tool device and splicing method of all-metal stator

Info

Publication number: CN113020830A
Application number: CN202110287573.7A
Authority: CN
Inventors: 易先中; 张仕帆; 刘航铭; 易军; 房军; 王宴滨; 柯扬船; 高德利
Original assignee: Yangtze University
Current assignee: Yangtze University
Priority date: 2021-03-17
Filing date: 2021-03-17
Publication date: 2021-06-25

Abstract

The invention provides a splicing tool device and a splicing method of an all-metal stator, which comprises a stator formed by splicing a plurality of metal bodies, and further comprises a chassis, wherein a driving mechanism is arranged on the chassis, a plurality of sliding mechanisms sliding along the center are arranged on the periphery of the driving mechanism, the number of the sliding mechanisms is the same as that of the metal bodies, a sliding clamp is arranged on each sliding mechanism, a sliding plate sliding is arranged on one side of a fixed baffle plate in each sliding clamp, and the metal bodies are arranged between the fixed baffle plate and the sliding plate; when the driving mechanism drives the sliding mechanisms to move towards the center, the metal bodies fixed on the sliding clamps are abutted against and spliced with each other to form the stator. The splicing tooling device is small in structure realization difficulty and low in cost. The stator can be suitable for the condition that a plurality of metal bodies are combined into the stator, the application range is wide, and the types of inner cavities for forming the stator are various. The splicing method has simple process, and the spliced stator is reliable in use, long in service life, resistant to high temperature and not easy to corrode, improves the mechanical property of the screw drill and is suitable for popularization and use.

Description

Splicing tool device and splicing method of all-metal stator

Technical Field

The invention relates to the field of assembling of metal screw drilling tool stators, in particular to a splicing tool device and a splicing method of an all-metal stator.

Background

At present, most of domestic external screw drilling tools adopt a conventional stator, and a rotor is plated with a hard chromium plating layer on the outer surface of alloy steel. When the screw drill works, the conventional stator is easy to damage due to the fact that the wall thickness of the conventional stator is unequal, and meanwhile, the performance characteristics of the screw drill are determined by the motor because the motor is a power part of the screw drill. When the stator is damaged, the use of the screw drill is seriously influenced, and meanwhile, the stator cannot be reused after being replaced, so that waste to a great extent is caused. In order to overcome the defects and improve the comprehensive efficiency of the screw drill, a scheme of the screw drill with the metal stator and the equal wall thickness is provided, the metal stator and the equal wall thickness are used for replacing the traditional stator, in particular to a splicing tool device and a splicing method thereof, a plurality of metal stators with the equal wall thickness are spliced together by using a splicing device to form a complete stator, compensation tests with different degrees are carried out at home and abroad, and the splicing has certain difficulty.

Chinese patent document CN 109538112 a describes a nested-spliced all-metal screw stator and a processing method thereof, including cutting a semi-cylindrical metal stator blank with a length of two stator leads to form an inner spiral, then cutting the inner spiral into two semi-cylindrical splices, pressing soldering tin into a fit gap after the planes of the two semi-cylindrical splices are attached to each other, and welding to form a cylindrical metal stator inner core; milling male thread lines with the same rotation direction at two ends of the stator inner core, and inserting the stator inner core into a metal pipe fitting; female thread lines are milled at positions, corresponding to the stator inner cores, of the inner walls of the two ends of the metal pipe fitting, and the stator inner cores are fixed in the metal pipe fitting through threads meshed with the metal pipe fitting. By adopting the method of screw thread locking fixation and metal stator split processing, the processing of the inner spiral surface of the stator is more convenient and accurate, the processing difficulty of the stator can be greatly reduced, the matching precision is improved, and further the working performance and the service life of the all-metal screw drill tool are improved. But this scheme has the structure to realize the degree of difficulty great, the higher problem of cost, and the situation that only is applicable to the synthetic stator of two metal bodies, and application scope is less, and the stator surface still needs to add a layer metal covering, and female thread line need be cut out to the both ends inner wall of metal pipe fitting, and the process is complicated and trivial details, and has certain harm to the stator, and the soldering tin of impressing welds, and welding process is equally loaded down with trivial details, and material consumption consuming time, and can not improve machining precision and machining efficiency with open processing.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a splicing tool device and a splicing method of an all-metal stator, and solve the problems that the stator cannot be formed by correspondingly bonding, fastening and splicing a plurality of processed metal bodies of the stator according to two, three or four parts, the splicing process of the stator is complex and tedious, the stator splicing consumes time and wastes materials, and the like.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows: a splicing tool device comprises a stator formed by splicing a plurality of metal bodies and a chassis, wherein a driving mechanism is arranged on the chassis, a plurality of sliding mechanisms sliding along the center are arranged on the periphery of the driving mechanism, the number of the sliding mechanisms is the same as that of the metal bodies, a sliding clamp is arranged on each sliding mechanism, a sliding plate sliding is arranged on one side of a fixed baffle plate in each sliding clamp, and the metal bodies are arranged between the fixed baffle plate and the sliding plate;

when the driving mechanism drives the sliding mechanisms to move towards the center, the metal bodies fixed on the sliding clamps are abutted against and spliced with each other to form the stator.

In the preferred scheme, the driving mechanism comprises a plurality of second screw rods, bevel gears and a motor, the bottoms of the bevel gears are fixedly connected with the motor, the bevel gears are arranged at one ends of the second screw rods, and the bevel gears are meshed with the bevel gears at the end parts of the second screw rods.

In the preferred scheme, slide mechanism includes fixing base and sliding block, is equipped with the screw hole on the sliding block, and the second lead screw supports on the fixing base, and the second lead screw passes through screw hole and slide mechanism threaded connection.

In the preferred scheme, be equipped with a plurality of chassis grooves on the chassis, the sliding block supports and leans on in the chassis groove to slide along the chassis groove.

In the preferred scheme, the sliding fixture is fixedly connected with the sliding mechanism, one end of a bottom plate in the sliding fixture is provided with a fixed baffle, the other end of the bottom plate is provided with a bearing seat, one end of a first screw rod is supported on the bearing seat, the other end of the first screw rod is supported on the fixed baffle, and the first screw rod is in threaded connection with the sliding plate.

In the preferred scheme, a sliding groove is formed in the bottom plate, and the bottom of the sliding plate is abutted against the inside of the sliding groove and slides along the sliding groove.

In the preferred scheme, be equipped with a plurality of mechanisms that spray between the slide mechanism, spray the mechanism and establish between two slide mechanism, spray the mechanism and just to the concatenation clearance of two metallics, spray the mechanism and spout the glue to the stator clearance of concatenation.

In the preferred scheme, the spraying mechanism is arranged on the chassis and comprises a spraying column and a plurality of spray heads, and the plurality of spray heads are fixedly arranged on the upper half part of the spraying column.

In a preferred scheme, an adhesive is arranged in the spraying column.

A splicing method of an all-metal stator comprises the following steps:

s1, manually rotating the first screw rod to enable the sliding plate to slide along the sliding groove, so that the distance between the fixed baffle and the sliding plate is increased;

s2, placing the metal body on the sliding plate, and reversely rotating the first screw rod so as to fix the metal body against between the fixed baffle and the sliding plate;

s3, driving a motor in the driving mechanism to enable the plurality of sliding mechanisms to drive the plurality of metal bodies to slide to corresponding positions along the center, and closing the motor;

s4, starting a spraying mechanism to spray the metal body;

s5, driving the motor in the driving mechanism again to enable the plurality of sliding mechanisms to drive the plurality of metal bodies to slide along the center to abut against each other and splice into a stator, and closing the motor after a period of time;

and S6, leaving a welding seam on one side of the joint surface of the metal bodies to weld and fasten the metal bodies together to form the stator cavity.

The invention provides a splicing tool device and a splicing method of all-metal stators. The sliding devices can also be suitable for the condition of the stator synthesized by two, three or a plurality of metal bodies, the application range is larger, and therefore the inner cavities of the stator can be formed in various types and have rich shapes. The splicing method is simple in process, has no damage to the inner cavity of the stator, saves time and materials, and can be used for open processing of the metal body, so that the processing precision and the processing efficiency are improved. The spliced stator is reliable in use, long in service life, high-temperature resistant in the bonding part, insoluble in water and not easy to corrode due to the fact that the splicing method is changed. The mechanical property of the screw drill is also improved, and the screw drill is suitable for popularization and application.

Drawings

The invention is further illustrated by the following examples in conjunction with the accompanying drawings:

FIG. 1 is an isometric view of the overall structure of the present invention.

Fig. 2 is a top view of the overall structure of the present invention.

Fig. 3 is an isometric view of a portion of the structure of the present invention.

Fig. 4 is an isometric view of a portion of the structure of the present invention.

Fig. 5 is an isometric view of the drive mechanism of the present invention.

Fig. 6 is an isometric view of the spray mechanism of the present invention.

Fig. 7 is an isometric view of a portion of the structure of the present invention.

FIG. 8 is an isometric view of a single metal body of the present invention.

Fig. 9 is an isometric view of a multiple metal body composite stator of the present invention.

In the figure: a chassis 1; a chassis bay 101; a slide jig 2; a first lead screw 201; a bearing housing 202; a sliding plate 203; a fixed baffle 204; a bottom plate 205; a chute 206; a slide mechanism 3; a fixed seat 301; a slider 302; a drive mechanism 4; a second lead screw 401; a bevel gear 402; a motor 403; a spraying mechanism 5; a spray column 501; a spray head 502; a metal body 6.

Detailed Description

Example 1:

as shown in fig. 1 to 9, a splicing tooling device includes a stator formed by splicing a plurality of metal bodies 6, and further includes a chassis 1, a driving mechanism 4 is disposed on the chassis 1, a plurality of sliding mechanisms 3 sliding along the center are disposed around the driving mechanism 4, the number of the sliding mechanisms 3 is the same as that of the metal bodies 6, a sliding clamp 2 is disposed on the sliding mechanism 3, a sliding plate 203 sliding is disposed on one side of a fixed baffle 204 in the sliding clamp 2, and the metal bodies 6 are disposed between the fixed baffle 204 and the sliding plate 203;

when the driving mechanism 4 drives the plurality of sliding mechanisms 3 to move towards the center, the plurality of metal bodies 6 fixed on the plurality of sliding clamps 2 are abutted against and spliced with each other to form a stator. According to the structure, the stator can be divided into two, three or four metal bodies and the like, the inner wall of each metal body can be processed with the spiral curved surface, after the metal bodies are welded and fastened into a whole, the spiral curved surfaces on the inner wall are combined to form the inner cavity of the inner spiral curved surface of the metal stator, the conventional stator does not have the inner cavity of the formed spiral curved surface, the inner cavity of the spiral curved surface is a spiral curve matched with the rotor, the wall thickness of the stator and the like can be used for rubber hanging, the thickness of rubber is reduced, and the adhesion area of the rubber and the metal is increased. The splicing tooling device can quickly and efficiently complete the splicing work of a plurality of metal bodies, so that the spliced metal bodies are stable and reliable in splicing, long in service life and small in splicing error.

In a preferred scheme, the driving mechanism 4 comprises a plurality of second screw rods 401, bevel gears 402 and a motor 403, the bottoms of the bevel gears 402 are fixedly connected with the motor 403, one ends of the second screw rods 401 are provided with the bevel gears, and the bevel gears 402 are meshed with the bevel gears at the ends of the second screw rods 401. By the structure, one driving motor can drive the plurality of screw rods simultaneously, the bevel gears are meshed with the bevel gears on the second screw rods, the sliding mechanisms 3 move towards the center of the chassis at the same speed, the phenomenon of uneven splicing can occur when metal bodies are spliced is eliminated, and the stator can be well attached.

In a preferred scheme, the sliding mechanism 3 includes a fixed seat 301 and a sliding block 302, a threaded hole is formed in the sliding block 302, the second lead screw 401 is supported on the fixed seat 301, and the second lead screw 401 is in threaded connection with the sliding mechanism 3 through the threaded hole. From this structure, second lead screw 401 supports on fixing base 301, has injectd the displacement of second lead screw, makes the second lead screw transmission moment of torsion steadily, has guaranteed that the sliding block steadily slides, and sliding block and second lead screw threaded connection, simple structure is practical, can realize that second lead screw axial rotation makes slide mechanism to the gliding function in chassis center.

In a preferred embodiment, a plurality of chassis grooves 101 are provided on the chassis 1, and the sliding block 302 abuts against the chassis grooves 101 and slides along the chassis grooves 101. From this structure, the simple messenger's slide mechanism who optimizes moves along the chassis groove to directional synthetic stator that makes a plurality of metal bodies stable avoids appearing the metal body synthetic in-process and can not appear rocking, makes the uneven phenomenon of stator laminating take place.

In a preferred scheme, the sliding fixture 2 is fixedly connected with the sliding mechanism 3, one end of a bottom plate 205 in the sliding fixture 2 is provided with a fixed baffle 204, the other end is provided with a bearing seat 202, one end of a first screw rod 201 is supported on the bearing seat 202, the other end is supported on the fixed baffle 204, and the first screw rod 201 is in threaded connection with the sliding plate 203. From this structure, the first section of fixed stop 204 reduces to be equipped with the half cylinder of inside salient, convenient inseparabler laminating metal body internal surface, the protruding cross-sectional plate in the middle of the sliding plate 203 makes the metal body separate with first lead screw, avoids the laminating of the motion influence metal body of first lead screw. The fixed baffle 204 is fixed at one end of the sliding fixture 2, so that the stroke of the metal body is limited, the metal body is prevented from falling, the rotating end of the first screw rod is arranged outside the sliding fixture, and the phenomenon that the first screw rod is mutually supported and the metal body cannot be attached together is avoided.

In a preferred scheme, a sliding groove 206 is arranged on the bottom plate 205, and the bottom of the sliding plate 203 abuts against the sliding groove 206 and slides along the sliding groove 206. According to the structure, the sliding plate is abutted against the sliding groove, the distance between the fixed baffle and the sliding plate is changed, the metal body can be simply and effectively clamped and taken out in the sliding clamp, the operation is simple, and the use is convenient.

In the preferred scheme, a plurality of spraying mechanisms 5 are arranged between the sliding mechanisms 3, the spraying mechanisms 5 are arranged between the two sliding mechanisms 3, the spraying mechanisms 5 are over against the splicing gaps of the two metal bodies 6, and the spraying mechanisms 5 spray glue to the spliced stator gaps. From this structure, all be equipped with between two slide mechanism 3 and spray the mechanism, make every of the metal body assemble the clearance and can both spout glue, will divide the metal body to correspond to bond as an organic wholely, correspond the interior helical curved surface inner chamber that combines to constitute this metal stator with the helical curved surface inner chamber of metal body inner wall from this.

In a preferred scheme, the spraying mechanism 5 is arranged on the chassis 1, the spraying mechanism 5 comprises a spraying column 501 and a plurality of spray heads 502, and the plurality of spray heads 502 are fixedly arranged on the upper half part of the spraying column 501. With the structure, the plurality of spray heads 502 are over against the clearance of the metal body, and the plurality of spray heads can uniformly spray on the clearance of the metal body, so that the metal body is stressed uniformly when being attached, the dislocation phenomenon can not occur, and the stability of the stator fixing and forming is ensured.

In a preferred embodiment, the spray column 501 is provided with an adhesive therein. By this structure, the binder is high temperature resistant, and is insoluble in water, also difficult corruption, and the adhesive makes a plurality of metal bodies cohere together, forms stable stator, except that the adhesion effect, has sealing effect in addition, avoids between the air admission metal body 6's the concatenation clearance, produces the corruption to the blocking phenomenon appears making the stator, influences the life of stator.

Example 2:

as shown in fig. 1 to 9, further description is made with reference to example 1:

manually rotating the first lead screw 201 in the forward direction to enable the sliding plate 203 to slide along the sliding groove 206, so that the distance between the fixed baffle 204 and the sliding plate 203 is increased; placing the metal body 6 on the sliding plate 203, wherein the inner surface of the metal body 6 is close to the fixed baffle 204, and reversely rotating the first screw rod 201, so that the metal body 6 is fixed and abutted between the fixed baffle 204 and the sliding plate 203, and is screwed down to ensure that the metal body does not slide, the bottom edges are not uniform, and the phenomenon that the middle section of the metal body is not vertical to the fixed baffle occurs; driving the motor 403 in the driving mechanism 4 to make the plurality of sliding mechanisms 3 drive the sliding fixture to slide along the center, so that the metal body on the sliding fixture slides to the optimal glue spraying position, and closing the motor 403 in the driving mechanism 4; starting the spraying mechanism 5, spraying the adhesive on the joint surface of the metal body to make the adhesive on the joint surface of the metal body uniform, and closing the spraying mechanism 5 after the adhesive on the joint surface of the metal body reaches the proper bonding thickness after a period of time; driving the motor 403 in the driving mechanism 4 again to make the plurality of sliding mechanisms 3 drive the plurality of metal bodies 6 to slide along the center to abut against each other and splice into a stator, and closing the motor 403 after the stator spliced by the plurality of metal bodies is bonded for a period of time; and a welding seam is reserved on one side of the joint surface of the metal bodies 6 to weld and fasten several metal bodies 6 together to form a stator cavity.

The above-described embodiments are merely preferred embodiments of the present invention, and should not be construed as limiting the present invention, and features in the embodiments and examples in the present application may be arbitrarily combined with each other without conflict. The protection scope of the present invention is defined by the claims, and includes equivalents of technical features of the claims. I.e., equivalent alterations and modifications within the scope hereof, are also intended to be within the scope of the invention.

Claims

1. The utility model provides a concatenation tool equipment, characterized by: the stator comprises a stator formed by splicing a plurality of metal bodies (6), and further comprises a chassis (1), wherein a driving mechanism (4) is arranged on the chassis (1), a plurality of sliding mechanisms (3) which slide along the center are arranged on the periphery of the driving mechanism (4), the number of the sliding mechanisms (3) is the same as that of the metal bodies (6), a sliding clamp (2) is arranged on the sliding mechanism (3), a sliding plate (203) is arranged on one side of a fixed baffle (204) in the sliding clamp (2), and the metal bodies (6) are arranged between the fixed baffle (204) and the sliding plate (203);

when the driving mechanism (4) drives the sliding mechanisms (3) to move towards the center, the metal bodies (6) fixed on the sliding clamps (2) are abutted against each other to be spliced into the stator.

2. The splicing tooling device of claim 1, wherein: the driving mechanism (4) comprises a plurality of second screw rods (401), bevel gears (402) and a motor (403), the bottoms of the bevel gears (402) are fixedly connected with the motor (403), one ends of the second screw rods (401) are provided with the bevel gears, and the bevel gears (402) are meshed with the bevel gears at the ends of the second screw rods (401).

3. The splicing tooling device of claim 1, wherein: the sliding mechanism (3) comprises a fixed seat (301) and a sliding block (302), a threaded hole is formed in the sliding block (302), the second screw rod (401) is supported on the fixed seat (301), and the second screw rod (401) is in threaded connection with the sliding mechanism (3) through the threaded hole.

4. The splicing tooling device of claim 1, wherein: a plurality of chassis grooves (101) are arranged on the chassis (1), and the sliding block (302) is abutted against the inside of the chassis grooves (101) and slides along the chassis grooves (101).

5. The splicing tooling device of claim 1, wherein: the sliding clamp (2) is fixedly connected with the sliding mechanism (3), one end of a bottom plate (205) in the sliding clamp (2) is provided with a fixed baffle (204), the other end of the bottom plate is provided with a bearing seat (202), one end of a first screw rod (201) is supported on the bearing seat (202), the other end of the first screw rod is supported on the fixed baffle (204), and the first screw rod (201) is in threaded connection with a sliding plate (203).

6. The splicing tooling device of claim 5, wherein: the bottom plate (205) is provided with a sliding groove (206), and the bottom of the sliding plate (203) is abutted against the sliding groove (206) and slides along the sliding groove (206).

7. The splicing tooling device of claim 1, wherein: be equipped with a plurality of mechanisms (5) that spray between slide mechanism (3), spray mechanism (5) and establish between two slide mechanism (3), spray mechanism (5) just to the concatenation clearance of two metallics (6), spray mechanism (5) and spout the glue to the stator clearance of concatenation.

8. The splicing tooling device of claim 1, wherein: the spraying mechanism (5) is arranged on the chassis (1), the spraying mechanism (5) comprises a spraying column (501) and a plurality of spray heads (502), and the plurality of spray heads (502) are fixedly arranged on the upper half part of the spraying column (501).

9. The splicing tooling device of claim 8, wherein: the spraying column (501) is internally provided with an adhesive.

10. A splicing method of an all-metal stator comprises the following steps:

s1, manually rotating the first screw rod (201) to enable the sliding plate (203) to slide along the sliding groove (206), so that the distance between the fixed baffle (204) and the sliding plate (203) is increased;

s2, placing the metal body (6) on the sliding plate (203), and reversely rotating the first screw rod (201) so as to fix the metal body (6) against between the fixed baffle (204) and the sliding plate (203);

s3, driving a motor (403) in the driving mechanism (4), enabling the plurality of sliding mechanisms (3) to drive the plurality of metal bodies (6) to slide to corresponding positions along the center, and closing the motor (403);

s4, starting the spraying mechanism (5), spraying the adhesive on the joint surface of the metal body (6), and closing the spraying mechanism (5) after a period of time;

s5, driving the motor (403) in the driving mechanism (4) again to enable the plurality of sliding mechanisms (3) to drive the plurality of metal bodies (6) to slide along the center to abut against each other and be spliced into a stator, and closing the motor (403) after a period of time;

and S6, leaving a welding seam on one side of the joint surface of the metal bodies (6) to weld and fasten several metal bodies (6) together to form the stator cavity.