CN215955066U - Main shaft mechanism for transformer production and jacketing machine using same - Google Patents

Abstract

The utility model provides a main shaft mechanism for transformer production and a jacketing machine using the same, wherein the main shaft mechanism for transformer production comprises a jig assembly, an X-axis module, a Y-axis module, a Z-axis module and a hitching leg auxiliary module; the jig assembly is used for placing a product; the X-axis module is used for providing an X-axis moving channel, and the jig assembly can slide along the straight line where the long side of the X-axis module is located. The Y-axis module is arranged on the X-axis module in a sliding mode and used for providing a Y-axis moving channel. The Z-axis module is vertically arranged on the Y-axis module and is used for providing a moving channel in the vertical direction. The hanging pin auxiliary module is arranged above the jig assembly and used for extruding the product hanging pins by matching with the jig assembly in an extruding manner. The main shaft mechanism for transformer production can convey products in multiple directions for processing operation, improves the production efficiency of the transformer, improves the precision of the products in the processing and production process, improves the quality of finished products of the products, and has strong practicability.

Description

Main shaft mechanism for transformer production and jacketing machine using same

Technical Field

The utility model relates to the field of transformer production equipment, in particular to a main shaft mechanism for transformer production and a jacketing machine using the same.

Background

With the rapid development of electronic technology, various household appliances and electronic devices are developed, and their performances are continuously improved, so that the requirements for electronic inductors and inductors of various specifications are continuously increased, for example, the design requirements of products with different performances on the number of turns, the number of layers, the wire outlet position, the number of layers of encapsulation, the method and the like of the coil of the electronic inductor are different.

In the current transformer processing production process, operations such as wire winding, hitching leg, rubber coating all are indispensable work, and the most still manual operation semi-automatization's of manual operation mechanical operation that still adopts of current working method needs the manual work to transfer the product accessory, and not only transformer production efficiency reduces, and manual operation machinery carries out operations such as wire winding, hitching leg, rubber coating moreover, and the precision is low, and the finished product specification is uneven.

Therefore, it is necessary to provide a main shaft mechanism for transformer production and a jacketing machine using the same to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a main shaft mechanism for transformer production and a jacketing machine using the same, wherein the main shaft mechanism for transformer production is provided with three mutually perpendicular axis modules for conveying product jigs, so that the problems of low production efficiency, low precision and uneven specification of finished products of manual operation semi-automatic mechanical operation in the prior art are solved.

In order to solve the technical problems, the technical scheme of the utility model is as follows: a main shaft mechanism for transformer production, comprising:

the jig assembly is used for placing a product;

the X-axis module is arranged on the mounting plane and used for providing an X-axis moving channel, and the jig assembly can slide along the straight line where the long side of the X-axis module is located;

the Y-axis module is arranged on the X-axis module in a sliding mode, the Y-axis module is used for providing a Y-axis moving channel, the projection of the Y-axis module on the installation plane is perpendicular to the projection of the X-axis module on the installation plane, and the jig assembly can slide along the straight line where the long edge of the Y-axis module is located;

the Z-axis module is vertically arranged on the Y-axis module and used for providing a moving channel in the vertical direction, the Z-axis module is connected with the Y-axis module in a sliding mode, and the jig assembly can slide along the straight line where the long side of the Z-axis module is located.

In the utility model, the main shaft mechanism for producing the transformer further comprises a hitching leg auxiliary module which is arranged above the jig component, is arranged on the Z-axis module in a sliding mode and is used for extruding the product hitching leg by being matched with the jig component in an extruding mode.

In the present invention, the jig assembly includes:

the module hanging plate is connected with the Z-axis module in a sliding mode and used for fixing a part;

the product jig is used for grabbing a product;

the main shaft motor is arranged on one side of the module hanging plate and connected with the module hanging plate, and the main shaft motor is used for driving the product jig to rotate; and

the spindle supporting seat is arranged between the spindle motor and the product jig and used for fixing the product jig.

In the present invention, the hitching leg auxiliary module includes:

one end of the transverse plate component is connected with the module hanging plate, and the other end of the transverse plate component extends to the upper part of the product jig;

the auxiliary pressing block is arranged above the product jig and used for pressing down the product hanging pins; and

the auxiliary pressing block cylinder is used for driving the hanging foot to enter the groove to assist the pressing block to move up and down.

In the present invention, the lateral plate member includes:

the transverse plate of the hitching leg auxiliary pressing block group is arranged at one end of the transverse plate part, and one end of the transverse plate of the hitching leg auxiliary pressing block group is connected with the module hanging plate; and

the other end of the transverse plate of the auxiliary pressing block cylinder is connected with the transverse plate of the auxiliary pressing block group of the hanging foot through an adjusting seat;

the hanger foot auxiliary pressing block group transverse plate is provided with a fixing hole, the fixing hole is matched with a bolt to connect the adjusting seat with the hanger foot auxiliary pressing block group transverse plate, the fixing hole is provided with a plurality of groups, and the fixing hole is arranged along a straight line where the long edge of the hanger foot auxiliary pressing block group transverse plate is located.

In the present invention, the adjusting seat includes:

the hanging foot auxiliary pressing block group moving guide rail is arranged on the hanging foot auxiliary pressing block group transverse plate, a straight line where the long edge of the hanging foot auxiliary pressing block group moving guide rail is located is perpendicular to a straight line where the long edge of the hanging foot auxiliary pressing block group transverse plate is located, and the auxiliary pressing block air cylinder transverse plate is in sliding connection with the hanging foot auxiliary pressing block group moving guide rail;

the hanging foot auxiliary pressing block group moving cylinder is arranged at one end of the hanging foot auxiliary pressing block group moving guide rail and is used for driving the transverse plate of the auxiliary pressing block cylinder to slide along the hanging foot auxiliary pressing block group moving guide rail; and

the hanging foot auxiliary pressing block group moving limiting block is arranged at the other end of the hanging foot auxiliary pressing block group moving guide rail and used for limiting the position of the auxiliary pressing block cylinder transverse plate.

In the present invention, the X-axis module includes:

an X-axis guide rail for guiding the component;

the X-axis motor is arranged at one end of the X-axis guide rail and used for driving the Y-axis module to slide along the X-axis guide rail; and

the X-axis motor is fixed at one end of the X-axis guide rail through a first connecting support.

In the present invention, the Y-axis module includes:

the second support is used for supporting a component, one end of the second support is connected with the X-axis guide rail in a sliding mode, and the other end of the second support is provided with a Y-axis motor fixing seat;

the Y-axis guide rail is arranged on the second bracket and used for guiding the component; and

and the Y-axis motor is arranged at one end of the Y-axis guide rail and is connected with the second support through a Y-axis motor fixing seat, and the Y-axis motor is used for driving the Z-axis module to slide along the Y-axis guide rail.

In the present invention, the Z-axis module comprises:

the third support is used for supporting a component, and the bottom end of the third support is connected with the Y-axis guide rail in a sliding manner;

the Z-axis guide rail is vertically arranged on one side of the third bracket and used for guiding the component; and

and the Z-axis motor is arranged at the top end of the Z-axis guide rail and is connected with the third support through a Z-axis motor fixing seat, and the Y-axis motor is used for driving the jig assembly to slide along the Z-axis guide rail.

The utility model also provides a jacketing machine which comprises the main shaft mechanism for producing the transformer.

Compared with the prior art, the utility model has the beneficial effects that: according to the spindle mechanism for producing the transformer, disclosed by the utility model, a product accessory is clamped through the jig component, the X-axis module, the Y-axis module and the Z-axis module are arranged for conveying the product jig, the three axis modules are mutually vertical, and the three axis modules drive the jig component to displace so as to be matched with each mechanism to work. The overall design of the main shaft mechanism for the production of the transformer is simplified and ingenious, the production efficiency of the transformer is improved, the precision of a product in a processing and production process is improved, the quality of a finished product is improved, and the practicability is high.

In addition, the top of tool subassembly is provided with the auxiliary module of hitching leg, and the supplementary briquetting cylinder in the auxiliary module of hitching leg is used for driving the hitching leg and goes into the supplementary briquetting up-and-down motion of groove to can cooperate the tool subassembly to compress tightly the product of rubber coating, promoted the practicality of mechanism.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required in the embodiments are briefly introduced below, and the drawings in the following description are only corresponding to some embodiments of the present invention.

Fig. 1 is a perspective view of a preferred embodiment of a spindle mechanism for transformer production of the present invention.

Fig. 2 is a schematic overall structure diagram of a preferred embodiment of the spindle mechanism for producing the transformer of the present invention.

Fig. 3 is a schematic structural diagram of a hitching leg auxiliary module of the preferred embodiment of the spindle mechanism for producing the transformer.

Fig. 4 is a schematic view of the overall structure of the preferred embodiment of the jacketing machine of the present invention.

Reference numerals: the jig assembly 14, the module hanging plate 141, the product jig 142, the spindle supporting base 143, the spindle motor 144, the X-axis module 11, the X-axis guide rail 111, the X-axis motor 112, the first support 113, the Y-axis module 12, the second support 121, the Y-axis motor fixing base 122, the Y-axis guide rail 123, the Y-axis motor 124, the Z-axis module 13, the third support 131, the Z-axis guide rail 132, the Z-axis motor 133, the Z-axis motor fixing base 134, the hitching leg auxiliary module 15, the transverse plate part 151, the hitching leg auxiliary pressing block transverse plate 1511, the fixing hole 1511a, the auxiliary pressing block cylinder transverse plate 1512, the adjusting base 1513, the hitching leg auxiliary pressing block moving guide rail 1513a, the hitching leg auxiliary pressing block moving cylinder 1513b, the hitching leg auxiliary pressing block moving limiting block 1513c, the hitching leg groove auxiliary pressing block 152, and the auxiliary pressing block cylinder 153.

Jacketing machine reference number: the automatic pipe penetrating mechanism 1, the main shaft mechanism 2 for transformer production, the quick rubber coating mechanism 3, the blanking mechanism 4, the double-guide-pin hitching leg mechanism 5, the automatic feeding mechanism 6 and the main panel 7.

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.

In the drawings, elements having similar structures are denoted by the same reference numerals.

The terms "first," "second," and the like in the terms of the utility model are used for descriptive purposes only and not for purposes of indication or implication relative importance, nor as a limitation on the order of precedence.

Referring to fig. 1, fig. 1 is a perspective view of a preferred embodiment of a spindle mechanism for producing a transformer according to the present invention. The following is a preferred embodiment of the spindle mechanism for producing a transformer according to the present invention, which can solve the above technical problems.

The utility model provides a main shaft mechanism for producing a transformer, which comprises a jig assembly 14, an X-axis module 11, a Y-axis module 12, a Z-axis module 13 and a hitching leg auxiliary module 15; wherein the jig assembly 14 is used for placing a product; the X-axis module 11 is arranged on the mounting plane, and the X-axis module 11 is used for providing an X-axis moving channel, so that the jig assembly 14 can slide along the straight line of the long edge of the X-axis module 11. The Y-axis module 12 is arranged on the X-axis module 11 in a sliding mode, and the Y-axis module 12 is used for providing a Y-axis moving channel; the projection of the Y-axis module 12 on the installation plane is perpendicular to the projection of the X-axis module 11 on the installation plane, so that the jig assembly 14 can slide along the straight line where the long side of the Y-axis module 12 is located. Z axle module 13 is vertical to be set up on Y axle module 12, and Z axle module 13 is used for providing the moving channel of vertical direction, and Z axle module 13 and Y axle module 12 sliding connection, tool subassembly 14 can be followed the long limit place straight line of Z axle module 13 and slided. The auxiliary hitching leg module 15 is arranged above the jig component 14, the auxiliary hitching leg module 15 is arranged on the Z-axis module 13 in a sliding manner, and the auxiliary hitching leg module 15 is used for being matched with the jig component 14 to extrude a product hitching leg.

According to the spindle mechanism for producing the transformer, disclosed by the utility model, a product accessory is clamped through the jig component, the X-axis module, the Y-axis module and the Z-axis module are arranged for conveying the product jig, the three axis modules are mutually vertical, and the three axis modules drive the jig component to displace so as to be matched with each mechanism to work. The overall design of the main shaft mechanism for the production of the transformer is simplified and ingenious, the production efficiency of the transformer is reduced, the precision of a product in the processing and production process is improved, the quality of a finished product is improved, and the practicability is high.

With reference to fig. 1, the structure of the jig assembly 14 in the present embodiment is described:

the jig assembly 14 in this embodiment includes a module hanging plate 141, a product jig 142, a spindle motor 144 and a spindle supporting base 143; the module hanging plate 141 is connected with the Z-axis module 13 in a sliding mode, and the module hanging plate 141 is used for fixing parts; the product fixture 142 is used for grabbing a product; the spindle motor 144 is disposed on one side of the module hanging plate 141, the spindle motor 144 is connected to the module hanging plate 141, and the spindle motor 144 is used for driving the product fixture 142 to rotate, so as to perform a winding operation. The main shaft supporting seat 143 is disposed at one side of the module hanging plate 141, and the main shaft supporting seat 143 is used for fixing the product fixture 142.

The tool subassembly 14 structural design is retrencied, and product tool 142 snatchs the product, and module link plate 141 supports whole tool subassembly 14, and product tool 142 just can carry out processes such as subsequent wire winding, hitching leg, rubber coating under spindle motor 144's drive, and the structure practicality is strong.

Referring to fig. 3, fig. 3 is a schematic structural diagram of a hitching leg auxiliary module according to a preferred embodiment of the spindle mechanism for producing a transformer of the present invention. The structure of the hitching leg auxiliary module 15 in this embodiment is explained:

in this embodiment, the hitching leg auxiliary module 15 includes a horizontal plate member 151, a hitching leg slot auxiliary pressing block 152 and an auxiliary pressing block cylinder 153; one end of the transverse plate member 151 is connected with the module hanging plate 141, and the other end of the transverse plate member 151 extends to the upper part of the product jig 142; preferably, the line of the long side of the horizontal plate member 151 in the present embodiment is parallel to the extending direction of the long side of the product fixture 142. The hanger bar groove-entering auxiliary pressing block 152 is arranged above the product jig 142 and is used for pressing down the product hanger bar; the hanger bar groove-entering auxiliary pressing block 152 is connected with the transverse plate component 151 through an auxiliary pressing block cylinder 153, and the auxiliary pressing block cylinder 153 is used for driving the hanger bar groove-entering auxiliary pressing block 152 to move up and down.

The auxiliary pressing block cylinder 153 in the hitching leg auxiliary module 15 is used for driving the hitching leg to enter the groove and assist the pressing block 152 to move up and down, so that the jig assembly 14 can be matched to compress the rubber-coated product, and the practicability of the mechanism is improved.

Further, the transverse plate component 151 comprises a foot-hanging auxiliary press block group transverse plate 1511 and an auxiliary press block cylinder transverse plate 1512; wherein, the transverse plate 1511 of the hitching leg auxiliary pressing block group is arranged at one end of the transverse plate part 151, and one end of the transverse plate 1511 of the hitching leg auxiliary pressing block group is connected with the module hanging plate 141; the auxiliary pressing block cylinder transverse plate 1512 is arranged at one end of the transverse plate component 151, and the other end of the auxiliary pressing block cylinder transverse plate 1512 is connected with the hanging foot auxiliary pressing block group transverse plate 1511 through the adjusting seat 1513.

Wherein, be provided with fixed orifices 1511a on hanger auxiliary pressing block group diaphragm 1511, fixed orifices 1511a cooperation bolt will adjust seat 1513 and be connected with hanger auxiliary pressing block group diaphragm 1511, fixed orifices 1511a is provided with a plurality of groups, and a plurality of fixed orifices 1511a are along the long limit place linear arrangement of hanger auxiliary pressing block group diaphragm 1511, thereby make the hanger go into the position adjustable of relative product tool 142 along the Y axle direction of the relative product tool of groove auxiliary pressing block 152, thereby make the position that the hanger goes into groove auxiliary pressing block 152 can be adjustable according to the position that the product rubber coating is ended, the practicality of device has been promoted.

Further, the adjusting seat 1513 includes a hitching leg auxiliary pressing block group moving guide rail 1513a, a hitching leg auxiliary pressing block group moving cylinder 1513b, and a hitching leg auxiliary pressing block group moving stopper 1513 c. The hanging foot auxiliary pressing block group moving guide rail 1513a is arranged on the hanging foot auxiliary pressing block group transverse plate 1511, a straight line of a long edge of the hanging foot auxiliary pressing block group moving guide rail 1513a is perpendicular to a straight line of a long edge of the hanging foot auxiliary pressing block group transverse plate 1511, and the auxiliary pressing block air cylinder transverse plate 1512 is in sliding connection with the hanging foot auxiliary pressing block group moving guide rail 1513 a.

The hitching leg auxiliary pressing block group moving cylinder 1513b is arranged at one end of the hitching leg auxiliary pressing block group moving guide rail 1513a, and the hitching leg auxiliary pressing block group moving cylinder 1513b is used for driving the auxiliary pressing block cylinder transverse plate 1512 to slide along the hitching leg auxiliary pressing block group moving guide rail 1513 a. The hitching leg auxiliary pressing block group moving limiting block 1513c is arranged at the other end of the hitching leg auxiliary pressing block group moving guide rail 1513a, and the hitching leg auxiliary pressing block group moving limiting block 1513c is used for limiting the position of the auxiliary pressing block cylinder transverse plate 1512.

The design of adjusting seat 1513 is simplified, and the auxiliary press block group moving cylinder 1513b of hitching leg can drive the auxiliary press block cylinder diaphragm 1512 to slide along the hitching leg auxiliary press block group moving guide rail 1513a, thereby further making the hitching leg enter the groove and auxiliary press block 152 adjustable along the X-axis direction, and improving the practicability of the hitching leg auxiliary module 15. In addition, the hitching leg auxiliary pressing block group moving limiting block 1513c is used for limiting the position of the auxiliary pressing block cylinder transverse plate 1512, so that the stability of the auxiliary pressing block 152 which is adjusted along the X-axis direction when the hitching leg enters the groove is improved.

Referring to fig. 2, fig. 2 is a schematic overall structure diagram of a preferred embodiment of the spindle mechanism for producing the transformer according to the present invention. The structure of the X-axis module 11 in this embodiment will be described in detail:

the X-axis module 11 includes an X-axis guide rail 111, an X-axis motor 112, and a first bracket 113; wherein the X-axis guide rail 111 is used for guiding the components; the X-axis motor 112 is arranged at one end of the X-axis guide rail, and the X-axis motor 112 is used for driving the Y-axis module 12 to slide along the X-axis guide rail 111; the X-axis motor 112 is fixed to one end of the X-axis guide rail by a first connecting bracket. The structure of the X-axis module 11 is simplified, the jig assembly 14 can grab products and can move freely in the X-axis direction, and the flexibility of product processing is increased.

The structure of the Y-axis module 12 in this embodiment will be described in detail with reference to fig. 2:

the Y-axis module 12 includes a second bracket 121, a Y-axis motor fixing base 122, a Y-axis guide rail 123 and a Y-axis motor 124; the second bracket 121 is used for supporting a component, one end of the second bracket 121 is slidably connected with the X-axis guide rail 111, and the other end of the second bracket 121 is provided with a Y-axis motor fixing seat 122; a Y-axis guide rail 123 is provided on the second support 121, the Y-axis guide rail 123 being used for guiding the member; the Y-axis motor 124 is disposed at one end of the Y-axis guide rail 123, the Y-axis motor 124 is connected to the second bracket 121 through the Y-axis motor fixing seat 122, and the Y-axis motor 124 is used for driving the Z-axis module 13 to slide along the Y-axis guide rail 123.

The structure of Y axle module 12 is simplified, and tool subassembly 14 can snatch the product and can carry out free motion in Y axle direction, has promoted main shaft mechanism's practicality.

The structure of the Z-axis module 13 in this embodiment will be described in detail with reference to fig. 2:

the Z-axis module 13 includes a third bracket 131, a Z-axis guide 132, and a Z-axis motor 133; the third bracket 131 is used for supporting components, and the bottom end of the third bracket 131 is connected with the Y-axis guide rail 123 in a sliding manner; a Z-axis guide rail 132 is vertically disposed at one side of the third bracket 131, and the Z-axis guide rail 132 is used for guiding a component; the Z-axis motor 133 is disposed on the top of the Z-axis guide rail 132, the Z-axis motor 133 is connected to the third bracket 131 through the Z-axis motor fixing seat 134, and the Y-axis motor 124 is used for driving the jig assembly 14 to slide along the Z-axis guide rail 132. The Z-axis module 13 is simple in structure, and the jig assembly 14 can grab products and can move freely in the Z-axis direction.

Further, the third bracket 131 in this embodiment includes a third sliding plate, a third vertical plate, and a third reinforcing plate, where the third sliding plate is slidably connected to the X-axis module, the third vertical plate is vertically disposed on the third sliding plate, the Z-axis guide rail 132 is fixed on one side of the third vertical plate, the third reinforcing plate is vertically disposed on the other side of the third vertical plate, and the third reinforcing plate is perpendicular to the third sliding plate and the third reinforcing plate.

The structure of Z axle module 13 is simplified, and tool subassembly 14 can snatch the product and can carry out free motion in Z axle direction, has further promoted main shaft mechanism's practicality. In addition, the third bracket 131 improves the stability of the overall structure of the Z-axis module 13 by being provided with a third reinforcing plate perpendicular to the third sliding plate and the third reinforcing plate.

As shown in fig. 4, fig. 4 is a schematic overall structure diagram of a jacketing machine according to a preferred embodiment of the present invention. The following is a preferred embodiment of the present invention that provides a jacketing machine that solves the above technical problems.

The utility model also provides a jacketing machine which comprises a main panel 7, a jacketing machine rubber coating mechanism 3, an automatic feeding mechanism 6, a double-guide-pin hitching leg mechanism 5, an automatic pipe penetrating mechanism 1, a blanking mechanism 4 and the main shaft mechanism 2 for transformer production.

Wherein the main panel 7 is used for fixing the components; the automatic pipe penetrating mechanism 1 is arranged on the main panel 7, and the automatic pipe penetrating mechanism 1 is used for performing pipe penetrating operation on winding; the automatic feeding mechanism 6 is arranged on the main panel 7, and the automatic feeding mechanism 6 is used for conveying winding materials; the double guide needle hitching leg mechanism 5 is arranged between the automatic pipe penetrating mechanism 1 and the automatic feeding mechanism 6, and the double guide needle hitching leg mechanism 5 is used for clamping a starting sleeve and a ending sleeve and hitching legs on a product; the jacketing machine encapsulation mechanism 3 is arranged on the main panel 7, the jacketing machine encapsulation mechanism 3 is located on one side of the automatic feeding mechanism 6, and the jacketing machine encapsulation mechanism 3 is used for encapsulating products; the main shaft mechanism 2 is arranged on the main panel 7, and the main shaft mechanism 2 is positioned among the mechanisms and is used for clamping the sleeve to move so as to be matched with the mechanisms to work; the blanking mechanism 4 for assembling the transformer is used for blanking.

The working principle of the spindle mechanism for producing the transformer is explained by combining the figures 1, 2 and 3:

when the mechanism works, firstly, a product is placed on the product jig 142 of the jig assembly 14, and then the product can freely move along the vertically arranged Z-axis direction under the driving of the Z-axis motor 133 of the Z-axis module 13; under the drive of the Y-axis module 12, the product can move freely in the Y-axis direction, and under the drive of the X-axis module 11, the product can move freely in the X-axis direction.

Then, after the product is moved to a corresponding place as required, the spindle motor 144 can drive the product fixture 142 to rotate, so as to perform subsequent processes of winding, hanging, encapsulating and the like. And when the product rubber coating, supplementary briquetting cylinder 153 in the supplementary module 15 of hitching leg is used for driving the hitching leg and goes into the supplementary briquetting 152 up-and-down motion of groove to can cooperate tool subassembly 14 to compress tightly the product of rubber coating, promoted the practicality of mechanism.

Finally, after the product process is completed, the product fixture 142 unloads the product and the mechanism component is reset.

Thus, the working process of the spindle mechanism for producing the transformer of the preferred embodiment is completed.

In summary, although the present invention has been described with reference to the preferred embodiments, the above-described preferred embodiments are not intended to limit the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, therefore, the scope of the present invention shall be determined by the appended claims.

Claims (10)

1. The utility model provides a main shaft mechanism is used in transformer production which characterized in that includes:

the jig assembly is used for placing a product;

the X-axis module is arranged on the mounting plane and used for providing an X-axis moving channel, and the jig assembly can slide along the straight line where the long side of the X-axis module is located;

the Y-axis module is arranged on the X-axis module in a sliding mode, the Y-axis module is used for providing a Y-axis moving channel, the projection of the Y-axis module on the installation plane is perpendicular to the projection of the X-axis module on the installation plane, and the jig assembly can slide along the straight line where the long edge of the Y-axis module is located;

the Z-axis module is vertically arranged on the Y-axis module and used for providing a moving channel in the vertical direction, the Z-axis module is connected with the Y-axis module in a sliding mode, and the jig assembly can slide along the straight line where the long side of the Z-axis module is located.

2. The spindle mechanism for transformer production according to claim 1, further comprising a hitching leg auxiliary module disposed above the jig assembly, wherein the hitching leg auxiliary module is slidably disposed on the Z-axis module and adapted to cooperate with the jig assembly to extrude the product hitching leg.

3. The spindle mechanism for transformer production according to claim 2, wherein the jig assembly comprises:

the module hanging plate is connected with the Z-axis module in a sliding mode and used for fixing a part;

the product jig is used for grabbing a product;

the main shaft motor is arranged on one side of the module hanging plate and connected with the module hanging plate, and the main shaft motor is used for driving the product jig to rotate; and

the spindle supporting seat is arranged between the spindle motor and the product jig and used for fixing the product jig.

4. The spindle mechanism for transformer production according to claim 3, wherein the hitching leg auxiliary module comprises:

one end of the transverse plate component is connected with the module hanging plate, and the other end of the transverse plate component extends to the upper part of the product jig;

the auxiliary pressing block is arranged above the product jig and used for pressing down the product hanging pins; and

the auxiliary pressing block cylinder is used for driving the hanging foot to enter the groove to assist the pressing block to move up and down.

5. The transformer production spindle mechanism according to claim 4, wherein the horizontal plate member includes:

the transverse plate of the hitching leg auxiliary pressing block group is arranged at one end of the transverse plate part, and one end of the transverse plate of the hitching leg auxiliary pressing block group is connected with the module hanging plate; and

the other end of the transverse plate of the auxiliary pressing block cylinder is connected with the transverse plate of the auxiliary pressing block group of the hanging foot through an adjusting seat;

the hanger foot auxiliary pressing block group transverse plate is provided with a fixing hole, the fixing hole is matched with a bolt to connect the adjusting seat with the hanger foot auxiliary pressing block group transverse plate, the fixing hole is provided with a plurality of groups, and the fixing hole is arranged along a straight line where the long edge of the hanger foot auxiliary pressing block group transverse plate is located.

6. The spindle mechanism for transformer production according to claim 5, wherein the adjustment seat comprises:

the hanging foot auxiliary pressing block group moving guide rail is arranged on the hanging foot auxiliary pressing block group transverse plate, a straight line where the long edge of the hanging foot auxiliary pressing block group moving guide rail is located is perpendicular to a straight line where the long edge of the hanging foot auxiliary pressing block group transverse plate is located, and the auxiliary pressing block air cylinder transverse plate is in sliding connection with the hanging foot auxiliary pressing block group moving guide rail;

the hanging foot auxiliary pressing block group moving cylinder is arranged at one end of the hanging foot auxiliary pressing block group moving guide rail and is used for driving the transverse plate of the auxiliary pressing block cylinder to slide along the hanging foot auxiliary pressing block group moving guide rail; and

the hanging foot auxiliary pressing block group moving limiting block is arranged at the other end of the hanging foot auxiliary pressing block group moving guide rail and used for limiting the position of the auxiliary pressing block cylinder transverse plate.

7. The transformer production spindle mechanism according to claim 1, wherein the X-axis module comprises:

an X-axis guide rail for guiding the component;

the X-axis motor is arranged at one end of the X-axis guide rail and used for driving the Y-axis module to slide along the X-axis guide rail; and

the X-axis motor is fixed at one end of the X-axis guide rail through a first connecting support.

8. The spindle mechanism for transformer production according to claim 7, wherein the Y-axis module comprises:

the second support is used for supporting a component, one end of the second support is connected with the X-axis guide rail in a sliding mode, and the other end of the second support is provided with a Y-axis motor fixing seat;

the Y-axis guide rail is arranged on the second bracket and used for guiding the component; and

and the Y-axis motor is arranged at one end of the Y-axis guide rail and is connected with the second support through a Y-axis motor fixing seat, and the Y-axis motor is used for driving the Z-axis module to slide along the Y-axis guide rail.

9. The spindle mechanism for transformer production according to claim 8, wherein the Z-axis module comprises:

the third support is used for supporting a component, and the bottom end of the third support is connected with the Y-axis guide rail in a sliding manner;

the Z-axis guide rail is vertically arranged on one side of the third bracket and used for guiding the component; and

and the Z-axis motor is arranged at the top end of the Z-axis guide rail and is connected with the third support through a Z-axis motor fixing seat, and the Y-axis motor is used for driving the jig assembly to slide along the Z-axis guide rail.

10. A jacketing machine comprising the transformer production spindle mechanism of any one of claims 1-9.

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