CN219405051U - Homogenization busbar vulcanizing device - Google Patents

Abstract

The utility model discloses a homogenizing busbar vulcanizing device, which comprises: the powder dipping barrel lifting device comprises a lifting mechanism and a horizontal position adjusting mechanism, wherein the horizontal position adjusting mechanism is arranged above the lifting mechanism, and a powder dipping barrel is arranged above the horizontal position adjusting mechanism; the suspension mechanism is connected with the hanging rail through a hanging hook; the shaking mechanism is connected with the suspension mechanism through a connecting clamping piece; the rotary platform is arranged between the horizontal position adjusting mechanism and the powder soaking barrel. According to the utility model, through optimizing the structure of the vulcanizing device, the height of the powder dipping barrel can be adjusted through the lifting mechanism, so that the powder dipping barrel can move up and down according to the production requirement, the powder dipping work can be completed better, and the horizontal position of the powder dipping barrel can be adjusted through the horizontal adjusting mechanism; the shaking mechanism clamps the suspension mechanism through the connecting clamping piece, and when the shaking mechanism shakes, the suspension mechanism can be driven to shake together, so that the powder soaking on the surface of the busbar is more uniform, and the superfluous powder on the surface of the busbar can be shaken off.

Description

Homogenization busbar vulcanizing device

Technical Field

The utility model belongs to the technical field of electronic component processing, and particularly relates to a homogenizing busbar vulcanizing device.

Background

The busbar is an important component of the switch equipment, the performance of the busbar directly affects the performance and operation safety of the switch equipment, and besides good conductive performance, the heat dissipation performance and insulation performance of the busbar have great influence on the switch equipment. In the busbar processing process, the busbar is usually placed in a fluidization tank for powder soaking treatment. When in powder dipping, the workpiece needing to be subjected to powder dipping is lifted into a vulcanizing tank for powder dipping treatment.

The busbar is an important component of the switch equipment, the performance of the busbar directly affects the performance and operation safety of the switch equipment, and besides good conductive performance, the heat dissipation performance and insulation performance of the busbar have great influence on the switch equipment.

In chinese CN201821330043.6, patent name is "flexible copper bar is in actual use, two ends of the flexible copper bar are contact ends fixedly connected with components and parts, and insulation treatment is not needed, but in order to prevent short circuit caused by contact of middle part of the flexible copper bar with other conductive materials, insulation treatment is performed on surface of middle part of the flexible copper bar (non-contact end), and there are various insulation treatment modes, such as dipping, powder dipping, heat shrinkage tube sleeving, etc"

In the prior Chinese patent CN201810496254.5, the patent name is specifically mentioned as a cutting device for the joint surface of a vulcanized busbar, wherein a layer of epoxy resin powder is solidified on the surface of the busbar to protect the busbar, and when the busbar is vulcanized, the heated busbar is integrally placed in a vulcanization tank. The vulcanizing tank is a powder dipping barrel, and most of the existing powder dipping barrels are fixedly arranged, so that the height and the horizontal position cannot be adjusted, and a plurality of inconveniences are brought to processing;

in addition, in the actual processing process, the problem of uneven powder soaking can occur in the process of powder soaking of the busbar, and meanwhile, excessive powder can be stained on the surface of the busbar, so that the material is wasted.

Disclosure of Invention

The utility model aims to: in order to overcome the defects, the utility model aims to provide the homogenizing busbar vulcanizing device, the structure of the vulcanizing device is optimized, the height of the powder dipping barrel can be adjusted through the lifting mechanism, so that the powder dipping barrel can move up and down according to the production requirement, the powder dipping work can be better completed, meanwhile, the horizontal position adjusting mechanism is also arranged, the horizontal position of the powder dipping barrel can be adjusted, the production requirement can be better met, and a plurality of convenience is provided for the powder dipping processing of products; the shaking mechanism clamps the suspension mechanism through the first clamping piece, and when the shaking mechanism shakes, the suspension mechanism can be driven to shake together, so that the powder soaking on the surface of the busbar is more uniform, and the redundant powder on the surface of the busbar can be shaken off.

The technical scheme is as follows: in order to achieve the above object, the present utility model provides a homogenizing busbar vulcanizing device, comprising:

the powder dipping barrel lifting device comprises a lifting mechanism and a horizontal position adjusting mechanism, wherein the horizontal position adjusting mechanism is arranged above the lifting mechanism, and a powder dipping barrel is arranged above the horizontal position adjusting mechanism;

the suspension mechanism is connected with the hanging rail through a lifting hook;

the shaking mechanism is connected with the suspension mechanism through a first clamping piece;

the rotary platform is arranged between the horizontal position adjusting mechanism and the powder soaking barrel.

The powder dipping barrel lifting device comprises a base and a lifting platform, wherein the lifting platform and the base are oppositely arranged up and down, the lower part of the lifting mechanism is connected with the base, the upper part of the lifting mechanism is connected with the lifting platform, limiting plates are arranged on two sides of the base and the lifting platform, and a sliding groove is formed between the limiting plates and the base and between the limiting plates and the lifting platform.

According to the homogenizing busbar vulcanizing device, the structure of the vulcanizing device is optimized, the height of the powder dipping barrel can be adjusted through the lifting mechanism, so that the powder dipping barrel can move up and down according to production requirements, powder dipping work can be completed better, meanwhile, the horizontal position adjusting mechanism is further arranged, the horizontal position of the powder dipping barrel can be adjusted, the production requirements can be met better, and a plurality of convenience is provided for powder dipping processing of products; the shaking mechanism clamps the suspension mechanism through the first clamping piece, when the shaking mechanism shakes, the suspension mechanism can be driven to shake together, so that powder soaking on the surface of the busbar is more uniform, and redundant powder on the surface of the busbar can be shaken off, so that the production requirement can be better met.

Further, the lifting mechanism adopts a scissor type lifting mechanism and comprises a group of first lifting brackets, a group of second lifting brackets, a group of third lifting brackets, a group of fourth lifting brackets and a lifting driving cylinder, wherein the first lifting brackets and the second lifting brackets are arranged in a crossing way, and the crossing parts are connected through connecting shafts; the third lifting brackets and the corresponding fourth lifting brackets are arranged in a crossing way, and the crossing part is hinged through a connecting shaft;

the lower parts of the two first lifting brackets are connected with the shaft sleeve on the base through connecting rods, the upper parts of the two first lifting brackets are connected through first cross bars, and the upper end parts of the two first lifting brackets are hinged with the lower end of the third lifting bracket through connecting shafts; the upper end part of the third lifting bracket is connected with a shaft sleeve on the lifting platform through a connecting rod;

the lower parts of the two second lifting brackets are connected with a lower sliding block through a connecting rod, the lower sliding block is arranged in a sliding groove, the upper end parts of the second lifting brackets are hinged with the lower end parts of the fourth lifting brackets through connecting shafts, the lower parts of the two fourth lifting brackets are connected through second cross bars, the upper end parts of the fourth lifting brackets are connected through connecting rods, the two ends of the connecting shafts are connected with an upper sliding block, and the upper sliding block is connected with the sliding groove on the lifting platform;

the lower parts of the two second lifting brackets are connected through a third cross rod, the bottoms of the lifting driving cylinders are connected with the third cross rod through cylinder mounting seats, and the upper output ends of the lifting driving cylinders are connected with the second cross rod through clamping blocks. The setting of scissor type elevating system can let the powder dipping barrel go up and down more steadily, further guarantees the stability of powder dipping.

Preferably, the horizontal position adjusting mechanism comprises an X-axis position adjusting mechanism and a Y-axis position adjusting mechanism, the X-axis position adjusting mechanism comprises a group of X-axis servo sliding tables and a first base plate, and the first base plate is arranged above the X-axis servo sliding tables and is in sliding connection with the X-axis servo sliding tables through a transverse sliding seat;

the Y-axis position adjusting mechanism comprises a Y-axis servo sliding table and a second base plate, wherein the Y-axis servo sliding table is arranged on the first base plate, and the second base plate is arranged above the Y-axis servo sliding table and is in sliding connection with the Y-axis servo sliding table through a longitudinal sliding seat.

Further, the hanging mechanism comprises a hook and a hanging frame, the hanging frame is arranged below the hook, and a group of second clamping pieces used for clamping the wire row are arranged on the hanging frame.

Preferably, the hanging frame comprises a group of transverse hanging frames, a group of longitudinal hanging frames and a connecting bracket, wherein the longitudinal hanging frames are arranged on two sides of the transverse hanging frames, two adjacent longitudinal hanging frames are connected with the transverse hanging frames through oblique supporting frames, the lower portion of the connecting bracket is connected with the transverse hanging frames, the upper portion of the connecting bracket is connected with the hanging hooks, and the second clamping piece is arranged on the longitudinal hanging frames. The structure of transverse hanging frame, vertical hanging frame and linking bridge sets up, effectively improves the structural strength of whole stores pylon, simultaneously, can improve the stationarity of soaking powder.

In addition, shake the mechanism and include vibration motor, vibration motor's top is equipped with the motor mount pad, one side of motor mount pad is equipped with first cylinder mounting bracket, be equipped with first actuating cylinder on the first cylinder mounting bracket, the below of first actuating cylinder is equipped with the second cylinder mounting bracket, be equipped with the second actuating cylinder on the second cylinder mounting bracket, first holder is connected with the second actuating cylinder.

Further, the rotary platform is arranged on the second base plate and comprises an output shaft, a servo motor and a cam assembly, the output shaft is arranged on the second base plate, the servo motor is arranged on the second base plate and on one side of the output shaft, the cam assembly is connected with the output shaft of the servo motor, and the cam assembly is matched with the output shaft.

Preferably, the outer sides of the lifting mechanism, the horizontal position adjusting mechanism and the rotating platform are all provided with protective covers.

Further preferably, the powder dipping barrel comprises a barrel body and an upper cover, wherein the upper cover is arranged on the barrel body and is provided with an opening, and the upper cover is obliquely arranged.

The technical scheme can be seen that the utility model has the following beneficial effects:

1. according to the homogenizing busbar vulcanizing device, the structure of the vulcanizing device is optimized, the height of the powder dipping barrel can be adjusted through the lifting mechanism, so that the powder dipping barrel can move up and down according to production requirements, powder dipping work can be completed better, meanwhile, the horizontal position adjusting mechanism is further arranged, the horizontal position of the powder dipping barrel can be adjusted, the production requirements can be met better, and a plurality of convenience is provided for powder dipping processing of products; the shaking mechanism clamps the suspension mechanism through the first clamping piece, when the shaking mechanism shakes, the suspension mechanism can be driven to shake together, so that powder soaking on the surface of the busbar is more uniform, and redundant powder on the surface of the busbar can be shaken off, so that the production requirement can be better met.

2. The lifting mechanism adopts a scissor type lifting mechanism, so that the powder dipping barrel can be lifted more stably, and the powder dipping stability is further ensured.

3. In the utility model, the upper cover is obliquely arranged. The inclined upper cover is arranged to enable the powder falling into the inner wall of the upper cover to slide into the barrel

4. The outer sides of the lifting mechanism and the horizontal position adjusting mechanism are respectively provided with a protective cover. The protective cover is arranged, so that a certain protection effect can be achieved on the lifting mechanism and the horizontal position adjusting mechanism, and meanwhile, the operation safety of equipment can be improved.

Drawings

FIG. 1 is a schematic structural view of a homogenizing busbar curing device according to the present utility model;

FIG. 2 is a schematic view of the installation of a suspension mechanism and a dithering mechanism of the present utility model;

FIG. 3 is a diagram showing the construction of the installation of the lifting mechanism and the horizontal position adjusting mechanism according to the present utility model;

FIG. 4 is a schematic view of a lifting mechanism according to the present utility model;

FIG. 5 is a view of the elevating mechanism of the present utility model from another perspective;

FIG. 6 is a schematic view of the installation of the lift cylinder of the present utility model;

FIG. 7 is a partial schematic view of a horizontal position adjustment mechanism according to the present utility model;

FIG. 8 is a schematic diagram of a rotary platform according to the present utility model;

FIG. 9 is a schematic view of a hanger according to the present utility model;

FIG. 10 is a schematic view of a longitudinal hanger according to the present utility model;

FIG. 11 is a schematic diagram of a dithering mechanism according to the present utility model;

FIG. 12 is a block diagram of another view of the dithering mechanism of the present utility model;

FIG. 13 is a schematic view of a structure of a clamping member for clamping a product according to the present utility model;

FIG. 14 is a schematic view of the installation of the shield of the present utility model;

in the figure: the dipping bucket lifting device 1, a lifting mechanism 11, a horizontal position adjusting mechanism 12, a base 13, a lifting platform 14, a limit post 15, a first lifting bracket 111, a group of second lifting brackets 112, a third lifting bracket 113, a fourth lifting bracket 114, a lifting driving cylinder 115, a first cross bar 116, a lower sliding block 117, a second cross bar 118, a third cross bar 119, an upper sliding block 120, an X-axis position adjusting mechanism 121, a Y-axis position adjusting mechanism 122, an X-axis servo sliding table 1211, a first base plate 1212, a transverse sliding seat 1213, a Y-axis servo sliding table 1221, a second base plate 1222, a longitudinal sliding seat 1223, a limit plate 131 and a sliding groove 132;

a powder dipping barrel 101, a barrel 1011 and an upper cover 1012;

the hanging mechanism 2, the hanging hook 201, the hanging rail 202, the hanging hook 21, the hanging rack 22, the second clamping piece 23, the transverse hanging rack 221, the longitudinal hanging rack 222, the connecting bracket 223 and the oblique supporting bracket 224;

the vibration motor 31, the motor mounting base 32, the first cylinder mounting frame 33, the first driving cylinder 34, the second cylinder mounting frame 35, the second driving cylinder 36 and the first clamping member 301;

the rotary platform 4, the output shaft 41, the servo motor 42 and the cam assembly 43;

clamping block 5, protection casing 6, protection frame 7, eccentric rotor 8.

Detailed Description

The utility model is further elucidated below in connection with the drawings and the specific embodiments.

Examples

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present utility model and should not be construed as limiting the utility model.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, unless otherwise specified, the meaning of "a plurality" is two or more, unless otherwise clearly defined.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present utility model, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

Example 1

A homogenizing busbar curing device as shown in figures 1 to 9, comprising:

the powder dipping barrel lifting device 1 comprises a lifting mechanism 11 and a horizontal position adjusting mechanism 12, wherein the horizontal position adjusting mechanism 12 is arranged above the lifting mechanism 11, and a powder dipping barrel 101 is arranged above the horizontal position adjusting mechanism 12;

a suspension mechanism 2, wherein the suspension mechanism 2 is connected with a hanging rail 202 through a hanging hook 201;

a shaking mechanism 3, wherein the shaking mechanism 3 is connected with the hanging mechanism 2 through a first clamping piece 301;

the rotary platform 4 is arranged between the horizontal position adjusting mechanism 12 and the powder soaking barrel 101.

The powder dipping barrel lifting device 1 comprises a base 13 and a lifting platform 14, wherein the lifting platform 14 and the base 13 are oppositely arranged up and down, the lower part of the lifting mechanism 11 is connected with the base 13, the upper part of the lifting mechanism is connected with the lifting platform 14, limiting plates 131 are arranged on two sides of the base 13 and the lifting platform 14, and sliding grooves 132 are formed between the limiting plates 131 and the base 13 and the lifting platform 14.

The lifting mechanism 11 adopts a scissor type lifting mechanism, and comprises a group of first lifting brackets 111, a group of second lifting brackets 112, a third lifting bracket 113, a fourth lifting bracket 114 and a lifting driving cylinder 115, wherein the first lifting brackets 111 and the second lifting brackets 112 are arranged in a crossing manner, and the crossing positions are connected through connecting shafts; the third lifting support 113 and the corresponding fourth lifting support 114 are arranged in a crossing manner, and the crossing part is hinged through a connecting shaft;

the lower parts of the two first lifting brackets 111 are connected with a shaft sleeve on the base 13 through a connecting rod, the upper parts of the two first lifting brackets 111 are connected through a first cross rod 116, and the upper end parts of the two first lifting brackets 111 are hinged with the lower end of the third lifting bracket 113 through a connecting shaft; the upper end of the third lifting bracket 113 is connected with a shaft sleeve on the lifting platform 14 through a connecting rod;

the lower parts of the two second lifting brackets 112 are connected with a lower sliding block 117 through a connecting rod, the lower sliding block 117 is arranged in a sliding groove 132, the upper end parts of the second lifting brackets 112 are hinged with the lower end parts of the fourth lifting brackets 114 through connecting shafts, the lower parts of the two fourth lifting brackets 114 are connected through a second cross rod 118, the upper end parts of the fourth lifting brackets 114 are connected through connecting rods, the two ends of the connecting shafts are connected with an upper sliding block 120, and the upper sliding block 120 is connected with the sliding groove 132 on the lifting platform 14;

the lower parts of the two second lifting brackets 112 are connected through a third cross rod 119, the bottoms of the lifting driving cylinders 115 are connected with the third cross rod 119 through cylinder mounting seats, and the upper output ends are connected with the second cross rod 118 through clamping blocks 5.

The horizontal position adjusting mechanism 12 comprises an X-axis position adjusting mechanism 121 and a Y-axis position adjusting mechanism 122, the X-axis position adjusting mechanism 121 comprises a group of X-axis servo sliding tables 1211 and a first base plate 1212, and the first base plate 1212 is arranged above the X-axis servo sliding tables 1211 and is slidably connected with the X-axis servo sliding tables 1211 through a lateral sliding seat 1213;

the Y-axis position adjusting mechanism 122 includes a Y-axis servo slipway 1221 and a second pad 1222, wherein the Y-axis servo slipway 1221 is disposed on the first pad 1212, and the second pad 1222 is disposed above the Y-axis servo slipway 1221 and is slidably connected with the Y-axis servo slipway 1221 through a longitudinal sliding seat 1223.

The hanging mechanism 2 comprises a hook 21 and a hanging frame 22, the hanging frame 22 is arranged below the hook 21, and a group of second clamping pieces 23 used for clamping the wire row are arranged on the hanging frame 22.

The hanging frame 22 comprises a group of transverse hanging frames 221, a group of longitudinal hanging frames 222 and a connecting bracket 223, wherein the longitudinal hanging frames 222 are arranged on two sides of the transverse hanging frames 221, two adjacent longitudinal hanging frames 222 are connected with the transverse hanging frames 221 through an oblique supporting frame 224, the lower part of the connecting bracket 223 is connected with the transverse hanging frames 221, the upper part of the connecting bracket 223 is connected with the hanging hook 21, and the second clamping piece 23 is arranged on the longitudinal hanging frames 222.

The shake mechanism 3 includes vibrations motor 31, the top of vibrations motor 31 is equipped with motor mount pad 32, one side of motor mount pad 32 is equipped with first cylinder mounting bracket 33, be equipped with first actuating cylinder 34 on the first cylinder mounting bracket 33, the below of first actuating cylinder 34 is equipped with second cylinder mounting bracket 35, be equipped with second actuating cylinder 36 on the second cylinder mounting bracket 35, first clamping piece 301 is connected with second actuating cylinder 36.

The rotary platform 4 is disposed on the second pad 1222, and the rotary platform 4 includes an output shaft 41, a servo motor 42, and a cam assembly 43, where the output shaft 41 is disposed on the second pad 1222, the servo motor 42 is disposed on the second pad 1222 and on one side of the output shaft 41, the cam assembly 43 is connected with the output shaft of the servo motor 42, and the cam assembly 43 is matched with the output shaft 41.

The outer sides of the lifting mechanism 11, the horizontal position adjusting mechanism 12 and the rotary platform 4 are provided with a protective cover 6.

Example 2

A homogenizing busbar curing device as shown in figures 1 to 14, comprising:

the powder dipping barrel lifting device 1 comprises a lifting mechanism 11 and a horizontal position adjusting mechanism 12, wherein the horizontal position adjusting mechanism 12 is arranged above the lifting mechanism 11, and a powder dipping barrel 101 is arranged above the horizontal position adjusting mechanism 12; a suspension mechanism 2, wherein the suspension mechanism 2 is connected with a hanging rail 202 through a hanging hook 201;

a shaking mechanism 3, wherein the shaking mechanism 3 is connected with the hanging mechanism 2 through a first clamping piece 301;

the rotary platform 4 is arranged between the horizontal position adjusting mechanism 12 and the powder soaking barrel 101.

The powder dipping barrel lifting device 1 comprises a base 13 and a lifting platform 14, as shown in fig. 1, 3 and 4, the lifting platform 14 and the base 13 are oppositely arranged up and down, the lower part of the lifting mechanism 11 is connected with the base 13, the upper part of the lifting mechanism is connected with the lifting platform 14, limiting plates 131 are arranged on two sides of the base 13 and the lifting platform 14, and sliding grooves 132 are formed between the limiting plates 131 and the base 13 and the lifting platform 14.

The lifting mechanism 11 adopts a scissor type lifting mechanism, and comprises a group of first lifting brackets 111, a group of second lifting brackets 112, a third lifting bracket 113, a fourth lifting bracket 114 and a lifting driving cylinder 115, as shown in fig. 3 to 6, wherein the first lifting brackets 111 and the second lifting brackets 112 are arranged in a crossing way, and the crossing parts are connected through connecting shafts; the third lifting support 113 and the corresponding fourth lifting support 114 are arranged in a crossing manner, and the crossing part is hinged through a connecting shaft;

the lower parts of the two first lifting brackets 111 are connected with a shaft sleeve on the base 13 through a connecting rod, the upper parts of the two first lifting brackets 111 are connected through a first cross rod 116, and the upper end parts of the two first lifting brackets 111 are hinged with the lower end of the third lifting bracket 113 through a connecting shaft; the upper end of the third lifting bracket 113 is connected with a shaft sleeve on the lifting platform 14 through a connecting rod;

the lower parts of the two second lifting brackets 112 are connected with a lower sliding block 117 through a connecting rod, the lower sliding block 117 is arranged in a sliding groove 132, the upper end parts of the second lifting brackets 112 are hinged with the lower end parts of the fourth lifting brackets 114 through connecting shafts, the lower parts of the two fourth lifting brackets 114 are connected through a second cross rod 118, the upper end parts of the fourth lifting brackets 114 are connected through connecting rods, the two ends of the connecting shafts are connected with an upper sliding block 120, and the upper sliding block 120 is connected with the sliding groove 132 on the lifting platform 14;

the lower parts of the two second lifting brackets 112 are connected through a third cross rod 119, the bottoms of the lifting driving cylinders 115 are connected with the third cross rod 119 through cylinder mounting seats, and the upper output ends are connected with the second cross rod 118 through clamping blocks 5.

The lifting platform further comprises two groups of limiting columns 15, as shown in fig. 6, wherein the limiting columns 15 are arranged on the base 13 and below the lifting platform 14, and the two groups of limiting columns are matched with each other.

The horizontal position adjusting mechanism 12 includes an X-axis position adjusting mechanism 121 and a Y-axis position adjusting mechanism 122, as shown in fig. 3 and 7, the X-axis position adjusting mechanism 121 includes a set of X-axis servo slipways 1211 and a first pad 1212, and the first pad 1212 is disposed above the X-axis servo slipways 1211 and is slidably connected to the X-axis servo slipways 1211 through a lateral sliding seat 1213;

the Y-axis position adjusting mechanism 122 includes a Y-axis servo slipway 1221 and a second pad 1222, wherein the Y-axis servo slipway 1221 is disposed on the first pad 1212, and the second pad 1222 is disposed above the Y-axis servo slipway 1221 and is slidably connected with the Y-axis servo slipway 1221 through a longitudinal sliding seat 1223.

The hanging mechanism 2 comprises a hook 21 and a hanging frame 22, as shown in fig. 1 and 2, the hanging frame 22 is arranged below the hook 21, and a group of second clamping pieces 23 for clamping the wire row are arranged on the hanging frame 22.

The hook 21 includes a connecting rod 211 and a hook body 212, as shown in fig. 2, the lower part of the connecting rod 211 is connected with a connecting bracket 223, the upper part is connected with the hook body 212, and a joint of the hook body 212 and the connecting rod 211 is provided with a joint block 213, and the connecting rod 211 is quadrilateral. The setting of quadrilateral connecting rod is convenient for the centre gripping of first holder, plays certain antiskid effect, avoids adopting cylindrical connecting rod, appears the not tight problem of centre gripping easily.

The hanging frame 22 comprises a set of transverse hanging frames 221, a set of longitudinal hanging frames 222 and a connecting bracket 223, as shown in fig. 2 and 9, the longitudinal hanging frames 222 are arranged on two sides of the transverse hanging frames 221, two adjacent longitudinal hanging frames 222 are connected with the transverse hanging frames 221 through an oblique supporting frame 224, the lower portion of the connecting bracket 223 is connected with the transverse hanging frames 221, the upper portion of the connecting bracket 223 is connected with the hanging hook 21, and the second clamping piece 23 is arranged on the longitudinal hanging frames 222. As shown in fig. 9 and 10, the longitudinal hanger 222 is provided with a set of adapters for mounting the second clamping member 23. It is conceivable that the adaptor can meet the requirement of clamping or suspending the second clamping member 23, for example, the first hook 2221 shown in fig. 4, and the end of the first hook 2221 faces upward, so that the second clamping member 23 can be prevented from being detached.

The shake mechanism 3 includes vibration motor 31, as shown in fig. 9, 11, 12, the top of vibration motor 31 is equipped with motor mount pad 32, one side of motor mount pad 32 is equipped with first cylinder mounting bracket 33, be equipped with first actuating cylinder 34 on the first cylinder mounting bracket 33, the below of first actuating cylinder 34 is equipped with second cylinder mounting bracket 35, be equipped with second actuating cylinder 36 on the second cylinder mounting bracket 35, first holder 301 is connected with second actuating cylinder 36. The first clamping member 301 is connected with the second driving cylinder 36; the vibration motor 31 further comprises a protection frame 7, as shown in fig. 12, wherein the protection frame 7 is arranged at the outer side of the vibration motor 31, and the upper end and the lower end of the protection frame are respectively connected with flanges at the upper end and the lower end of the vibration motor 31. The arrangement of the protective frame 7 can play a good role in protecting the vibration motor and provide the working safety of the vibration motor.

As shown in fig. 5, a limiting plate 37 is disposed above the motor mounting base 32, a set of fixing plates 38 for connecting with the frame are disposed above the limiting plate 37, a set of buffer connectors 39 are disposed at four corners between the motor mounting base 32 and the limiting plate 37, and an eccentric rotor 8 of the vibration motor 31 is disposed on an output shaft of the vibration motor 31. When the buffer connector works, the buffer connector can play a good role in buffering, so that the jitter is stable.

As shown in fig. 11 and 12, the shaking mechanism 3 is connected with the frame, and is connected with the suspension mechanism 2 through a first clamping member 301, the first clamping member 301 is L-shaped, and includes a mounting portion and a clamping portion, the mounting portion is connected with the second cylinder mounting frame 35, and the clamping portion is provided with a U-shaped opening.

The rotary platform 4 is disposed on the second pad 1222, and the rotary platform 4 includes an output shaft 41, a servo motor 42, and a cam assembly 43, where the output shaft 41 is disposed on the second pad 1222, the servo motor 42 is disposed on the second pad 1222 and on one side of the output shaft 41, the cam assembly 43 is connected with the output shaft of the servo motor 42, and the cam assembly 43 is matched with the output shaft 41.

The outer sides of the lifting mechanism 11, the horizontal position adjusting mechanism 12 and the rotary platform 4 are provided with a protective cover 6.

The powder dipping barrel 101 comprises a barrel 1011 and an upper cover 1012, as shown in fig. 12, the upper cover 1012 is arranged on the barrel 1011, an opening is arranged on the upper cover 1012, the upper cover 1012 is obliquely arranged, and the chamfering range is 30-60 degrees; facilitating the powder to slide into the barrel.

The working principle of the homogenizing busbar vulcanizing device in the embodiment is as follows: during operation, the hanging mechanism 2 moves to the upper part of the powder dipping barrel 101 along the hanging rail 202 through the hanging hook 201, the lifting driving cylinder 115 drives the second cross rod 118 to move upwards, the second cross rod 118 drives the fourth lifting bracket 114 to move upwards when moving upwards, and the third lifting bracket 113 and the fourth lifting bracket 114 are hinged, so that the lifting platform 14 is pushed upwards under the joint pushing of the third lifting bracket 113 and the fourth lifting bracket 114, the powder dipping barrel 101 is driven to move upwards together during the upward operation of the lifting platform 14, thereby realizing the lifting, until the product is immersed into powder, during the powder dipping process, the servo motor 42 in the rotating platform 4 drives the cam assembly 43 to operate during the rotation of the cam assembly 43, the cam assembly drives the output shaft 41 to rotate, and meanwhile, the vibration motor 31 in the shaking mechanism 3 operates, the first clamping piece 301 drives the hanging mechanism 2 to vibrate, so that the uniformity of the powder dipping is improved, and the redundant powder is shaken off simultaneously;

when the lifting driving cylinder 115 drives the second cross rod 118 to move downwards, the second cross rod 118 drives the fourth lifting bracket 114 and the third lifting bracket 113 to simultaneously move downwards;

the horizontal direction of the powder dipping barrel can be adjusted according to the requirement, namely, the X-axis servo sliding table 121 drives the transverse sliding seat 1213 to drive the first base plate 1212 and other components above the first base plate 1212 to move together, so that the transverse movement of the powder dipping barrel is realized, and the Y-axis servo sliding table 1221 drives the longitudinal sliding seat 1223 to drive the second base plate 1222 to move, so that the movement of the longitudinal position of the powder dipping barrel is realized.

In addition, the position of the first clamping member 301 in the dithering mechanism 3 can be adjusted, that is, the first driving cylinder 34 drives the second cylinder mounting frame 35 to adjust the height thereof, and the second driving cylinder 36 drives the first clamping member 301 to move to adjust the horizontal position thereof.

The foregoing is merely a preferred embodiment of the utility model, and it should be noted that modifications could be made by those skilled in the art without departing from the principles of the utility model, which modifications would also be considered to be within the scope of the utility model.

Claims (10)

1. A homogenization busbar vulcanization device is characterized in that: comprising the following steps:

the powder dipping barrel lifting device (1), wherein the powder dipping barrel lifting device (1) comprises a lifting mechanism (11) and a horizontal position adjusting mechanism (12), the horizontal position adjusting mechanism (12) is arranged above the lifting mechanism (11), and a powder dipping barrel (101) is arranged above the horizontal position adjusting mechanism (12);

the suspension mechanism (2) is connected with the hanging rail (202) through a hanging hook (201);

the shaking mechanism (3) is connected with the suspension mechanism (2) through a first clamping piece (301);

the rotary platform (4) is arranged between the horizontal position adjusting mechanism (12) and the powder soaking barrel (101).

2. The homogenizing busbar curing device of claim 1, wherein: the powder dipping barrel lifting device (1) comprises a base (13) and a lifting platform (14), wherein the lifting platform (14) and the base (13) are oppositely arranged up and down, the lower part of the lifting mechanism (11) is connected with the base (13), the upper part of the lifting mechanism is connected with the lifting platform (14), limiting plates (131) are arranged on two sides of the base (13) and the lifting platform (14), and sliding grooves (132) are formed between the limiting plates (131) and the base (13) and between the limiting plates and the lifting platform (14).

3. The homogenizing busbar curing device of claim 2, wherein: the lifting mechanism (11) adopts a scissor type lifting mechanism, and comprises a group of first lifting brackets (111), a group of second lifting brackets (112), a third lifting bracket (113), a fourth lifting bracket (114) and a lifting driving cylinder (115), wherein the first lifting brackets (111) and the second lifting brackets (112) are arranged in a crossing manner, and the crossing positions are connected through connecting shafts; the third lifting brackets (113) and the corresponding fourth lifting brackets (114) are arranged in a crossing way, and the crossing part is hinged through a connecting shaft;

the lower parts of the two first lifting brackets (111) are connected with a shaft sleeve on the base (13) through connecting rods, the upper parts of the two first lifting brackets (111) are connected through a first cross rod (116), and the upper end parts of the two first lifting brackets are hinged with the lower end of the third lifting bracket (113) through connecting shafts; the upper end part of the third lifting bracket (113) is connected with a shaft sleeve on the lifting platform (14) through a connecting rod;

the lower parts of the two second lifting brackets (112) are connected with a lower sliding block (117) through a connecting rod, the lower sliding block (117) is arranged in a sliding groove (132), the upper end parts of the second lifting brackets (112) are hinged with the lower end parts of the fourth lifting brackets (114) through connecting shafts, the lower parts of the two fourth lifting brackets (114) are connected through a second cross rod (118), the upper end parts of the fourth lifting brackets (114) are connected through connecting rods, the two ends of the connecting shafts are connected with an upper sliding block (120), and the upper sliding block (120) is connected with the sliding groove (132) on the lifting platform (14);

the lower parts of the two second lifting brackets (112) are connected through a third cross rod (119), the bottoms of the lifting driving cylinders (115) are connected with the third cross rod (119) through cylinder mounting seats, and the upper output ends are connected with the second cross rod (118) through clamping blocks (5).

4. The homogenizing busbar curing device of claim 2, wherein: the horizontal position adjusting mechanism (12) comprises an X-axis position adjusting mechanism (121) and a Y-axis position adjusting mechanism (122), the X-axis position adjusting mechanism (121) comprises a group of X-axis servo sliding tables (1211) and a first base plate (1212), and the first base plate (1212) is arranged above the X-axis servo sliding tables (1211) and is in sliding connection with the X-axis servo sliding tables (1211) through a transverse sliding seat (1213);

the Y-axis position adjusting mechanism (122) comprises a Y-axis servo sliding table (1221) and a second base plate (1222), the Y-axis servo sliding table (1221) is arranged on the first base plate (1212), and the second base plate (1222) is arranged above the Y-axis servo sliding table (1221) and is in sliding connection with the Y-axis servo sliding table (1221) through a longitudinal sliding seat (1223).

5. The homogenizing busbar curing device of claim 2, wherein: the hanging mechanism (2) comprises a hook (21) and a hanging frame (22), wherein the hanging frame (22) is arranged below the hook (21), and a group of second clamping pieces (23) used for clamping the wire row are arranged on the hanging frame (22).

6. The homogenizing busbar curing device of claim 5, wherein: the hanging rack (22) comprises a group of transverse hanging racks (221), a group of longitudinal hanging racks (222) and a connecting bracket (223), wherein the longitudinal hanging racks (222) are arranged on two sides of the transverse hanging racks (221), two adjacent longitudinal hanging racks (222) are connected with the transverse hanging racks (221) through oblique supporting frames (224), the lower part of the connecting bracket (223) is connected with the transverse hanging racks (221), the upper part of the connecting bracket is connected with the hanging hooks (21), and the second clamping piece (23) is arranged on the longitudinal hanging racks (222).

7. The homogenizing busbar curing device of claim 1, wherein: the shake mechanism (3) comprises a shake motor (31), a motor mounting seat (32) is arranged above the shake motor (31), a first cylinder mounting frame (33) is arranged on one side of the motor mounting seat (32), a first driving cylinder (34) is arranged on the first cylinder mounting frame (33), a second cylinder mounting frame (35) is arranged below the first driving cylinder (34), a second driving cylinder (36) is arranged on the second cylinder mounting frame (35), and the first clamping piece (301) is connected with the second driving cylinder (36).

8. The homogenizing busbar curing device of claim 2, wherein: the rotary platform (4) is arranged on a second base plate (1222), the rotary platform (4) comprises an output shaft (41), a servo motor (42) and a cam assembly (43), the output shaft (41) is arranged on the second base plate (1222), the servo motor (42) is arranged on the second base plate (1222) and on one side of the output shaft (41), the cam assembly (43) is connected with the output shaft of the servo motor (42), and the cam assembly (43) is matched with the output shaft (41).

9. The homogenizing busbar curing device of claim 1, wherein: the outer sides of the lifting mechanism (11), the horizontal position adjusting mechanism (12) and the rotating platform (4) are respectively provided with a protective cover (6).

10. The homogenizing busbar curing device of claim 2, wherein: the powder soaking barrel (101) comprises a barrel body (1011) and an upper cover (1012), wherein the upper cover (1012) is arranged on the barrel body (1011), an opening is formed in the upper cover (1012), and the upper cover (1012) is obliquely arranged.