CN114336206B - Glass sealing connector melting sealing device and method - Google Patents

Abstract

The invention discloses a glass sealing connector melting and sealing device and a method in the technical field of glass sealing connector melting and sealing, and the device comprises a motor, a heating kettle, a plurality of heating rods are fixedly arranged in the heating kettle in an annular array around the axis of the heating kettle, the lower end of the heating kettle is fixedly arranged on the outer wall of the motor through a support, an output shaft of the motor is coaxially connected with a hollow driving shaft through a transmission mechanism, a main eccentric plate is fixedly arranged on the outer wall of the driving shaft, a fixed rod is rotatably arranged on the inner wall of the driving shaft, the bottom end of the fixed rod is fixedly arranged on a motor shell through the support, and a main centering gear is coaxially and fixedly arranged at the upper end of the fixed rod; the invention solves the problem that the service life of the glass sealing connector is shortened due to the fact that the sintered glass is easy to concentrate stress because of the uneven heating in the melting and sintering process in the static melting and sintering mode of the existing glass connector by adopting a single clamp when the existing glass connector is melted and sintered.

Description

Fusion sealing device and method for glass sealing connector

Technical Field

The invention relates to the technical field of fusion sealing of glass sealing connectors, in particular to a fusion sealing device and method of a glass sealing connector.

Background

Compared with a plastic sealing connector, the glass sintering vacuum sealing connector has the following advantages:

the glass and metal are mutually infiltrated to form a mixed chemical bond when being sealed, and the bonding force of the mixed chemical bond is far greater than that of plastic adhered metal. The glass-to-metal encapsulated connector has sufficient tensile and torsional strength.

High temperature resistance, glass is an inorganic non-metallic material which has a high softening point temperature and which does not release any harmful components when used in a high temperature environment. The plastic is not high temperature resistant, and volatile to harmful components in high temperature environment. This is why some connectors, particularly those having one end that needs to be completely sealed and used as a working interface, cannot be made of plastic as an insulating material;

the glass has good sealing performance and low leakage rate, has good electrical performance parameters as common insulating materials, can completely meet the design requirements of the connector on the insulation resistance and dielectric withstand voltage of the glass, has strong anti-corrosion capability and is suitable for severe environments.

When the existing glass connector is subjected to melt sintering, a single clamp is adopted to carry out a static melt sintering mode, uneven heating is easily caused in the melt sintering process, and uneven phenomenon also occurs after cooling, so that the problem that stress concentration easily occurs in the sintered glass, the glass sealing connector is cracked in the later use process, and the service life of the glass sealing connector is reduced; secondly, due to melting and sintering, the glass is in a liquid state in the process, so that the problem that the thickness of the subsequent glass is uneven due to large shaking is easily caused, and the problem that the glass sealing connector is interfered in the plugging and unplugging process, so that the glass is cracked is caused.

Based on the above, the invention provides a fusion sealing device and a fusion sealing method for a glass sealing connector, which are used for solving the problems.

Disclosure of Invention

The invention aims to provide a fusion sealing device and a fusion sealing method for a glass sealing connector, which aim to solve the problems that when the existing glass connector in the background art is fused and sintered, a static fusion sintering mode is carried out by adopting a single clamp, uneven heating is easy to occur in the fusion sintering process, and uneven phenomenon also occurs after cooling, so that the sintered glass is easy to have stress concentration, the glass sealing connector is cracked in the later use process, and the service life of the glass sealing connector is shortened; secondly, because of melting and sintering, the glass is in a liquid state in the process, so that the subsequent glass is easy to have uneven thickness due to large shaking, and the glass sealing connector is interfered in the plugging and unplugging process, so that the glass is cracked.

In order to achieve the purpose, the invention provides the following technical scheme: a fusion sealing device of a glass sealing connector comprises a motor, a heating kettle, a plurality of heating rods fixedly arranged in the heating kettle in an annular array around the axis of the heating kettle, the lower end of the heating kettle is fixedly arranged on the outer wall of the motor through a bracket, the output shaft of the motor is coaxially connected with a hollow driving shaft through a speed change mechanism in a transmission way, a main eccentric plate is fixedly arranged on the outer wall of the driving shaft, a fixed rod is rotatably arranged on the inner wall of the driving shaft, the bottom end of the fixed rod is fixedly arranged on the motor shell through a bracket, the upper end of the fixed rod is coaxially and fixedly provided with a main centering gear, the main eccentric plate is rotatably provided with a main driven shaft, the outer wall of the main driven shaft is coaxially and fixedly provided with a main central gear engaged with the main central gear, two groups of eccentric differential devices are arranged at the upper ends of the driving and driven shafts, and a carrier device used for clamping and placing the glass sealing connector is arranged at the upper end of each differential device.

As a further scheme of the invention, the differential device comprises a revolution table rotatably arranged on the outer wall of a driving and driven shaft, the driving and driven shaft penetrates through the upper end of the revolution table and is fixedly provided with an auxiliary eccentric plate, an auxiliary eccentric shaft is rotatably arranged on the auxiliary eccentric plate, an auxiliary eccentric gear is fixedly arranged on the outer wall of the auxiliary eccentric shaft, the outer side of the auxiliary eccentric gear is provided with a reversing mechanism capable of enabling the auxiliary eccentric shaft to rotate, and one end of the auxiliary eccentric shaft penetrating through the heating kettle is provided with a carrier device for clamping and placing a glass sealing connector.

As a further scheme of the invention, the carrier device comprises a carrier ring plate which is coaxially and fixedly arranged at the upper end of the auxiliary eccentric shaft through a support and has gradually increased radius, a through hole for placing a glass sealing connector is formed in the carrier ring plate, a positioning base for positioning the glass sealing connector is fixedly arranged at the lower end of the through hole, a pressurizing block for pressurizing molten glass in the glass sealing connector is arranged at the upper end of the carrier ring plate positioned on the through hole, and an eccentric compensation device is arranged at the joint of the auxiliary eccentric shaft and the heating kettle.

As a further scheme of the invention, the eccentric compensation device comprises a primary compensation plate which is rotatably arranged on the bottom surface of the heating kettle and coaxial with the fixed rod, and a secondary compensation plate which is coaxial with the driving shaft and the driven shaft is rotatably arranged on the primary compensation plate.

As a further scheme of the invention, the reversing mechanism comprises a first-stage tooth arranged on the outer side wall of the revolution table, a reversing annular toothed plate rotatably arranged at the lower end of the heating kettle through a support is meshed at the outer end of the first-stage tooth, the reversing annular toothed plate is connected to an output shaft of the motor through a speed change mechanism at the lower end in a transmission manner, and a second-stage tooth meshed with the auxiliary eccentric gear is arranged on the inner wall of the revolution table.

As a further scheme of the invention, the speed change mechanism comprises a revolution annular plate fixedly arranged at the lower end of a reverse rotation annular gear plate through a support, the revolution annular plate is coaxially and rotatably arranged on the outer wall of the driving shaft, the lower end of the revolution annular plate is provided with a plurality of speed change gears in an annular array manner around the axis of the revolution annular plate, the outer ends of the speed change gears are meshed with the same speed change ring rack, the lower ends of the speed change ring racks are coaxially and fixedly arranged on the output shaft of the motor through the support, and the inner sides of the speed change gears are all meshed with the outer wall of the driving shaft.

As a further scheme of the invention, the motor adopts a speed reducing motor, so that the equipment obtains larger torque and the working efficiency is improved.

The fusion sealing method of the glass sealing connector comprises the following specific steps:

the method comprises the following steps: transferring a glass sealing connector to be subjected to fusion sealing to an equipment site, firstly installing a positioning base on a carrier ring plate, sequentially placing the glass sealing connector to be subjected to fusion sealing into a through hole on the carrier ring plate, and then placing a pressurizing block at the upper end of the glass sealing connector;

step two: starting the heating device to heat, starting the equipment motor to enable the carrier ring plate to revolve and rotate in the heating kettle, and enabling the glass sealing connector to revolve and rotate in the heating kettle in a full-angle manner, so that heating dead angles are avoided, and the molten states of glass in the glass sealing connector are different, so that the problems that the glass is heated unevenly, stress exists and the glass is cracked are solved;

step three: and cooling the melted glass sealing connector, taking down the pressurizing block after cooling, taking out the glass sealing connector, neatly stacking, and transferring to the next processing procedure.

Compared with the prior art, the invention has the beneficial effects that:

1. the invention drives the driving shaft through the speed change mechanism, then drives the main eccentric plate to revolve around the main centering gear at the end of the fixed rod through the driving shaft, so that the main centering gear outside the main driving shaft on the main eccentric plate rotates, thereby completing the first-stage deceleration revolution and rotation, then drives the auxiliary eccentric plate at the upper end to revolve through the revolution of the auxiliary eccentric plate driven by the driving shaft, and then drives the auxiliary eccentric gear to rotate through the reversal mechanism, thereby completing the revolution and rotation of the auxiliary eccentric shaft, thereby completing the second-stage deceleration revolution and rotation, thereby enabling the carrier ring plate at the upper end of the auxiliary eccentric shaft to revolve and rotate, and through the first-stage and second-stage revolution and rotation, thereby enabling any one glass sealing connector on the carrier ring plate to move in a heating kettle without dead angle, thereby solving the problem that the existing fixed glass sealing connector carries out the fixed and static melting sintering and cooling modes, the problem that bubbles exist in the glass, so that stress concentration is easy to occur, and the problem that the service life of the glass sealing connector is shortened is caused.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description 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 creative efforts.

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic side-view, partially cross-sectional structural view of the present invention;

FIG. 3 is an enlarged view of the structure at A in FIG. 2 according to the present invention;

FIG. 4 is an enlarged view of the structure at B in FIG. 2 according to the present invention;

FIG. 5 is a schematic view of the present invention in partial cross-section from the top view of the left side;

FIG. 6 is an enlarged view of the structure of FIG. 5 at C according to the present invention;

FIG. 7 is a schematic view of the differential assembly of the present invention;

FIG. 8 is a schematic view of the flow structure of the method of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

the device comprises a heating kettle 11, a heating rod 12, a driving shaft 13, a main eccentric plate 14, a main centering gear 15, a main driving shaft 16, a main centering gear 17, a revolution table 18, a secondary eccentric shaft 19, a secondary eccentric gear 20, a fixed rod 21, a secondary eccentric plate 22, a carrier ring plate 23, a through hole 24, a positioning base 25, a pressurizing block 26, a primary compensating plate 30, a secondary compensating plate 31, a primary tooth 33, a reverse ring tooth plate 34, a secondary tooth 35, a revolution ring plate 37, a speed change gear 38 and a speed change ring rack 39.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: a glass sealing connector melting sealing device comprises a motor, and comprises a heating kettle 11, wherein a plurality of heating rods 12 are fixedly arranged in the heating kettle 11 in an annular array manner around the axis of the heating kettle 11, the lower end of the heating kettle 11 is fixedly arranged on the outer wall of the motor through a support, a hollow driving shaft 13 is coaxially connected with an output shaft of the motor through a speed change mechanism in a transmission manner, a main eccentric plate 14 is fixedly arranged on the outer wall of the driving shaft 13, a fixed rod 21 is rotatably arranged on the inner wall of the driving shaft 13, the bottom end of the fixed rod 21 is fixedly arranged on a motor shell through the support, a main centering gear 15 is coaxially and fixedly arranged at the upper end of the fixed rod 21, a main driven shaft 16 is rotatably arranged on the main eccentric plate 14, a main centering gear 17 meshed with the main centering gear 15 is coaxially and fixedly arranged on the outer wall of the main driven shaft 16, two groups of eccentric differential devices are arranged at the upper ends of the main driven shaft 16, and a carrier device for clamping and placing a glass sealing connector is arranged at the upper end of the differential device; the differential device comprises a revolution table 18 which is rotatably arranged on the outer wall of a driving and driven shaft 16, an auxiliary eccentric plate 22 is fixedly arranged at the upper end of the driving and driven shaft 16, which penetrates through the revolution table 18, an auxiliary eccentric shaft 19 is rotatably arranged on the auxiliary eccentric plate 22, an auxiliary eccentric gear 20 is fixedly arranged on the outer wall of the auxiliary eccentric shaft 19, a reversing mechanism which can enable the auxiliary eccentric shaft 19 to rotate is arranged on the outer side of the auxiliary eccentric gear 20, and a carrier device which is used for clamping and placing a glass sealing connector is arranged at one end of the auxiliary eccentric shaft 19, which penetrates through the heating kettle 11; the carrier device comprises a carrier ring plate 23 which is coaxially and fixedly arranged at the upper end of the auxiliary eccentric shaft 19 through a bracket and has gradually increased radius, a through hole 24 for placing a glass sealing connector is formed in the carrier ring plate 23, a positioning base 25 for positioning the glass sealing connector is fixedly arranged at the lower end of the through hole 24, a pressurizing block 26 for pressurizing molten glass in the glass sealing connector is arranged at the upper end of the carrier ring plate 23 positioned on the through hole 24, and an eccentric compensation device is arranged at the joint of the auxiliary eccentric shaft 19 and the heating kettle 11;

firstly, the device is assembled (as shown in fig. 1 and 2, the device adopts a cylindrical arrangement and a symmetrical arrangement, the left and the right of the device are not distinguished, and the upper end of the device is not seen from the upper part to the lower part of fig. 1), and the heating kettle 11 is arranged at the upper end of the device, so that the problem that the movement mechanism of the device works in an overheated environment, the mechanical fatigue of the device occurs, and the device is damaged is avoided; transferring a glass sealing connector to be subjected to fusion sealing to an equipment site, firstly installing a positioning base on a carrier ring plate, sequentially placing the glass sealing connector to be subjected to fusion sealing into a through hole on the carrier ring plate, and then placing a pressurizing block at the upper end of the glass sealing connector;

when the invention is used, the motor of the device is started, the motor rotates to drive the driving shaft 13 to rotate through the speed change mechanism, the driving shaft 13 rotates to drive the main eccentric plate 14 to rotate, the main eccentric plate 14 rotates to drive the main driven shaft 16 to revolve, when the main driven shaft 16 revolves, the main eccentric gear 17 outside the main driven shaft 17 revolves around the main centering gear 15 fixedly arranged at the end of the fixed rod 21, so that the main eccentric gear 17 rotates, the main eccentric gear 17 rotates to drive the main driven shaft 16 to rotate, the main driven shaft 16 rotates and revolves to drive the upper revolution table 18 to revolve, simultaneously, the main driven shaft 16 rotates to drive the upper auxiliary eccentric plate 22 to revolve, the auxiliary eccentric plate 22 revolves to drive the auxiliary eccentric shaft 19 to revolve, wherein the reverse rotation mechanism also synchronously works to drive the auxiliary eccentric shaft 19 to rotate and revolve (as shown in figures 2 and 5, wherein the two-stage rotation and revolution speed are different through two-stage deceleration revolution and rotation, so that the carrier device at the upper end performs both revolution and rotation, thereby the carrier device is switched to the heating kettle 11, and the carrier device is provided with two revolution axes, so that the glass sealing connectors on the carrier device can move to the inside of the heating kettle 11 without dead angles, thereby avoiding the problem of heating dead angles), so that the sub-eccentric shaft 19 drives the carrier ring plate 23 to rotate in a rotation and revolution manner, the carrier ring plate 23 rotates to move the molten glass sealing connector at the upper end to be sintered in the heating kettle 11, the moving path is wider through the heating kettle 11, and the glass sealing connector on the carrier device does not have dead angles and moves in the heating kettle 11, so that the problem of heating dead angles is avoided; secondly, the revolution speed and the rotation speed of the carrier ring plate 23 are further reduced by two times of eccentric deceleration, so that the problem of non-uniform thickness of glass caused by the centrifugation of the fused glass sealing connector is solved;

the invention drives the driving shaft 13 through the speed change mechanism, then drives the main eccentric plate 14 to revolve around the main centering gear 15 at the end of the fixed rod 21 through the driving shaft 13, so that the main centering gear 17 outside the main driving shaft 16 on the main eccentric plate 14 rotates, thereby completing the first-stage deceleration revolution and rotation, then drives the auxiliary eccentric plate 22 at the upper end to revolve through the main driving shaft 16, so that the auxiliary eccentric shaft 19 at the upper end revolves, then drives the auxiliary eccentric gear 20 to rotate through the reversing mechanism, thereby completing the revolution and rotation of the auxiliary eccentric shaft 19, thereby completing the second-stage deceleration revolution and rotation, so that the carrier ring plate 23 at the upper end of the auxiliary eccentric shaft 19 revolves and rotates, and passes through the first-stage and second-stage revolution and rotation, thereby enabling any one glass sealing connector on the carrier ring plate 23 to move in the heating kettle 11 without dead angle, thereby solving the problem that the existing fixed glass sealing connector performs the fixed and static melting sintering and cooling mode, the problem that bubbles exist in the glass, so that stress concentration is easy to occur, and the problem that the service life of the glass sealing connector is shortened is caused.

As a further scheme of the invention, the eccentric compensation device comprises a primary compensation plate 30 which is rotatably arranged on the bottom surface of the heating kettle 11 and is coaxial with the fixed rod 21, and a secondary compensation plate 31 which is coaxial with the driving and driven shaft 16 is rotatably arranged on the primary compensation plate 30;

when the invention is used, the secondary eccentric shaft 19 revolves, so that the secondary compensation plate 31 revolves on the primary compensation plate 30 to compensate the revolution of the secondary eccentric shaft 19, and when the primary driving shaft 16 revolves, the primary compensation plate 30 revolves at the bottom end of the heating kettle 11 to compensate the revolution of the primary driving shaft 16.

As a further scheme of the invention, the reversing mechanism comprises a first-stage tooth 33 arranged on the outer side wall of the revolving table 18, a reversing annular toothed plate 34 rotatably arranged at the lower end of the heating kettle 11 through a support is meshed at the outer end of the first-stage tooth 33, the reversing annular toothed plate 34 is in transmission connection with an output shaft of the motor through a speed change mechanism at the lower end, and a second-stage tooth 35 meshed with the auxiliary eccentric gear 20 is arranged on the inner wall of the revolving table 18; the speed change mechanism comprises a revolution annular plate 37 fixedly arranged at the lower end of the reverse rotation annular gear plate 34 through a support, the revolution annular plate 37 is coaxially and rotatably arranged on the outer wall of the driving shaft 13, the lower end of the revolution annular plate 37 is provided with a plurality of speed change gears 38 in an annular array manner around the axis of the revolution annular plate, the outer ends of the speed change gears 38 are meshed with the same speed change annular rack 39, the lower ends of the speed change annular racks 39 are coaxially and fixedly arranged on the output shaft of the motor through the support, and the inner sides of the speed change gears 38 are all meshed with the outer wall of the driving shaft 13;

when the invention is used, the motor drives the change ring rack 39 to rotate, the change ring rack 39 rotates to drive the change gear 38 to rotate, the change gear 38 rotates to drive the driving shaft 13 to rotate, the driving shaft 13 and the change gear 38 are driven by the change ring rack 39 to generate revolution force, so that the change gear 38 drives the revolution ring plate 37 to revolve, the revolution ring plate 37 revolves to drive the reverse ring toothed plate 34 to rotate, the rotation speed of the reverse ring toothed plate 34 is opposite to the rotation direction of the driving shaft 13 and lower than that of the driving shaft 13, the reverse ring toothed plate 34 rotates to drive the primary teeth 33 outside the revolution table 18 (wherein the revolution table 18 is revolved by the driving shaft 16 and always abuts against the reverse ring toothed plate 34) so as to enable the revolution table 18 to rotate, the revolution table 18 rotates to drive the secondary eccentric gear 20 to rotate through the secondary teeth 35 at the upper end, thereby driving the secondary eccentric shaft 19 to rotate, thereby, two-stage speed reduction is realized, the revolution of the auxiliary eccentric shaft 19 is influenced by the two revolution shafts, and differential revolution and autorotation are carried out, thereby avoiding the problem of heating dead angles.

As a further scheme of the invention, the motor adopts a speed reducing motor, so that the equipment obtains larger torque and the working efficiency is improved.

The fusion sealing method of the glass sealing connector comprises the following specific steps:

the method comprises the following steps: transferring a glass sealing connector to be subjected to fusion sealing to an equipment site, firstly installing a positioning base on a carrier ring plate, sequentially placing the glass sealing connector to be subjected to fusion sealing into a through hole on the carrier ring plate, and then placing a pressurizing block at the upper end of the glass sealing connector;

step two: starting the heating device to heat, starting the equipment motor to enable the carrier ring plate to revolve and rotate in the heating kettle, and enabling the glass sealing connector to revolve and rotate in the heating kettle in a full-angle manner, so that heating dead angles are avoided, and the molten states of glass in the glass sealing connector are different, so that the problems that the glass is heated unevenly, stress exists and the glass is cracked are solved;

step three: and cooling the melted glass sealing connector, taking down the pressurizing block after cooling, taking out the glass sealing connector, neatly stacking, and transferring to the next processing procedure.

Claims (8)

1. A glass sealing connector melting sealing device comprises a motor, and is characterized in that: comprises a heating kettle (11), a plurality of heating rods (12) are fixedly arranged inside the heating kettle (11) around the axis of the heating kettle in an annular array manner, the lower end of the heating kettle (11) is fixedly arranged on the outer wall of a motor through a support, the output shaft of the motor is coaxially connected with a hollow driving shaft (13) through a speed change mechanism in a transmission manner, a main eccentric plate (14) is fixedly arranged on the outer wall of the driving shaft (13), a fixed rod (21) is rotatably arranged on the inner wall of the driving shaft (13), the bottom end of the fixed rod (21) is fixedly arranged on a motor shell through the support, a main centering gear (15) is coaxially and fixedly arranged at the upper end of the fixed rod (21), a main driving shaft (16) is rotatably arranged on the main eccentric plate (14), and a main centering gear (17) meshed with the main centering gear (15) is coaxially and fixedly arranged on the outer wall of the main centering shaft (16), two groups of eccentric differential devices are arranged at the upper ends of the driving and driven shafts (16), and a carrier device used for clamping and placing the glass sealing connector is arranged at the upper ends of the differential devices.

2. The glass-sealing connector fusion sealing apparatus of claim 1, wherein: the differential device comprises a revolution table (18) rotatably arranged on the outer wall of a driving and driven shaft (16), an auxiliary eccentric plate (22) is fixedly arranged at the upper end of the driving and driven shaft (16) penetrating through the revolution table (18), an auxiliary eccentric shaft (19) is rotatably arranged on the auxiliary eccentric plate (22), an auxiliary eccentric gear (20) is fixedly arranged on the outer wall of the auxiliary eccentric shaft (19), a reversing mechanism capable of enabling the auxiliary eccentric shaft (19) to rotate is arranged on the outer side of the auxiliary eccentric gear (20), and a carrier device used for clamping and placing the glass sealing connector is arranged at one end of the auxiliary eccentric shaft (19) penetrating through the heating kettle (11).

3. The glass-sealing connector fusion sealing apparatus of claim 2, wherein: the carrier device comprises a carrier ring plate (23) which is coaxially and fixedly arranged at the upper end of the auxiliary eccentric shaft (19) through a support and has a radius which is gradually increased, a through hole (24) for placing a glass sealing connector is formed in the carrier ring plate (23), a positioning base (25) for positioning the glass sealing connector is fixedly arranged at the lower end of the through hole (24), a pressurizing block (26) for pressurizing molten glass in the glass sealing connector is arranged at the upper end of the carrier ring plate (23) positioned on the through hole (24), and an eccentric compensation device is arranged at the joint of the auxiliary eccentric shaft (19) and the heating kettle (11).

4. A glass-sealing connector fusion sealing apparatus as in claim 3 wherein: the eccentric compensation device comprises a primary compensation plate (30) which is rotatably arranged on the bottom surface of the heating kettle (11) and coaxial with the fixed rod (21), and a secondary compensation plate (31) which is coaxial with the driving and driven shaft (16) is rotatably arranged on the primary compensation plate (30).

5. The glass-sealing connector fusion sealing apparatus of claim 2, wherein: the reversal mechanism includes one-level tooth (33) that revolving stage (18) lateral wall was seted up, one-level tooth (33) outer end meshing has and rotates anti-rotation ring pinion rack (34) that set up at heating cauldron (11) lower extreme through the support, anti-rotation ring pinion rack (34) are connected to on the motor output shaft through the speed change mechanism transmission of lower extreme, revolving stage (18) inner wall is seted up with vice eccentric gear (20) engaged with second grade tooth (35).

6. The glass-sealing connector fusion sealing apparatus of claim 5, wherein: the speed change mechanism comprises a revolution annular plate (37) fixedly arranged at the lower end of a reverse revolution annular toothed plate (34) through a support, the revolution annular plate (37) is coaxially rotated and arranged on the outer wall of the driving shaft (13), the lower end of the revolution annular plate (37) rotates around an axis annular array of the revolution annular plate and is provided with a plurality of speed change gears (38), the outer ends of the speed change gears (38) are meshed with a same speed change annular rack (39), the lower ends of the speed change annular racks (39) are coaxially and fixedly arranged on a motor output shaft through supports, and the inner sides of the speed change gears (38) are all meshed on the outer wall of the driving shaft (13).

7. The glass-sealing connector fusion sealing apparatus of claim 5, wherein: the motor adopts a speed reducing motor for enabling the equipment to obtain larger torque and improving the working efficiency.

8. A method for fusion-sealing a glass sealing connector, which is applied to the fusion-sealing device of the glass sealing connector according to any one of claims 1 to 7, wherein the method comprises the following steps: the fusion sealing method of the glass sealing connector comprises the following specific steps:

the method comprises the following steps: transferring a glass sealing connector to be subjected to fusion sealing to an equipment site, firstly installing a positioning base on a carrier ring plate, sequentially placing the glass sealing connector to be subjected to fusion sealing into a through hole on the carrier ring plate, and then placing a pressurizing block at the upper end of the glass sealing connector;

step two: starting the heating device to heat, starting the equipment motor to enable the carrier ring plate to revolve and rotate in the heating kettle, and enabling the glass sealing connector to revolve and rotate in the heating kettle in a full-angle manner, so that heating dead angles are avoided, and the molten states of glass in the glass sealing connector are different, so that the problems that the glass is heated unevenly, stress exists and the glass is cracked are solved;

step three: and cooling the melted glass sealing connector, taking down the pressurizing block after cooling, taking out the glass sealing connector, neatly stacking, and transferring to the next processing procedure.

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