CN214213070U

CN214213070U - Automatic material receiver for numerical control turning and milling combination

Info

Publication number: CN214213070U
Application number: CN202023161096.XU
Authority: CN
Inventors: 黄太钦; 王飞宇
Original assignee: Shenzhen Sowin Precision Machine Tool Co ltd
Current assignee: Shenzhen Sowin Precision Machine Tool Co ltd
Priority date: 2020-12-23
Filing date: 2020-12-23
Publication date: 2021-09-17
Anticipated expiration: 2030-12-23

Abstract

The utility model relates to an automatic material receiver for numerical control turning and milling combination, which comprises a bearing seat and a material receiving hopper, wherein the bearing seat is rotationally connected with a first output shaft sleeve and a power input component; a gear box body is fixed on the first output shaft sleeve, a driving shaft extending into the gear box body is fixedly arranged on the bearing seat, and the driving shaft coaxially penetrates through the first output shaft sleeve; the gear box body is rotatably connected with an output shaft, the output shaft is driven by a driving shaft to rotate, and a rotating seat is fixedly connected to the output shaft; a second output shaft sleeve sleeved on the output shaft is fixedly arranged on the gear box body; the rotating seat is rotatably provided with a first output gear and a second output gear, and the receiving hopper is driven by the second output gear to rotate to perform receiving and discharging actions; rational in infrastructure and very compact, small, the rotation output of the three direction of butt joint hopper just can be realized to single input, in addition, can also set for the drive ratio between each transmission as required and obtain the rotation angle that wants, and the stroke of connecing the blowing is great.

Description

Automatic material receiver for numerical control turning and milling combination

Technical Field

The utility model relates to a compound lathe technical field of numerical control turn-milling, more specifically say, relate to a compound automatic material receiver that uses of numerical control turn-milling.

Background

The small parts are machined on the numerical control turning and milling compound machine tool, particularly when mass production is carried out, the workpieces are directly dropped into the machine tool after being cut off, the parts are easy to damage, great labor cost is needed when the parts are picked up, and the automatic material receiver which is small in size, large in stroke and diversified in adjusting angle is needed.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model lies in, to prior art's above-mentioned defect, provide a combined automatic material receiver of numerical control turn-milling, still provide a combined automatic material receiving method of numerical control turn-milling.

The utility model provides a technical scheme that its technical problem adopted is:

the automatic material receiver for the numerical control turning and milling combination is constructed and comprises a bearing seat and a material receiving hopper, wherein a first output shaft sleeve and a power input assembly for driving the first output shaft sleeve to rotate are rotatably connected to the bearing seat; a gear box body is fixed on the first output shaft sleeve, a driving shaft extending into the gear box body is fixedly arranged on the bearing seat, and the driving shaft coaxially penetrates through the first output shaft sleeve; an output shaft is rotatably connected to the gear box body, the output shaft is driven by the driving shaft to rotate, and a rotating seat is fixedly connected to the output shaft; a second output shaft sleeve sleeved on the output shaft is fixedly arranged on the gear box body; the rotating seat is rotatably provided with a first output gear driven by the second output shaft sleeve to rotate and a second output gear driven by the first output gear to rotate, and the material receiving hopper is driven by the second output gear to rotate to perform material receiving and discharging actions.

The utility model discloses a numerical control turn-milling is compound with automatic material receiver, wherein, power input subassembly includes driving cylinder, the expansion end of driving cylinder is connected with power input shaft; the power input shaft is provided with a strip-shaped tooth socket; and a first external gear matched with the strip-shaped tooth socket is coaxially fixed on the first output shaft sleeve.

The utility model discloses a numerical control turn-milling is compound with automatic material receiver, wherein, the bearing frame includes the shell, be provided with on the shell and supply the trompil that the power input shaft stretched into and for the linear bearing of power input shaft direction; the shell and the shell of the driving cylinder are fixedly connected through a fixing plate.

Numerical control turn-milling is compound with automatic material receiver, wherein, in the shell or it is fixed to be provided with the centre gripping on the shell the first centre gripping mounting of drive shaft.

The utility model discloses a numerical control turn-milling is compound uses automatic material receiver, wherein, the outside rotation of drive shaft is connected with first swivel bearing; the inner wall of the first output shaft sleeve is provided with a supporting block for supporting the outer ring of the first rotating bearing and a movable sheet which is matched with the supporting block and clamps and fixes the outer ring of the first rotating bearing; the movable sheet is detachably connected with the first output shaft sleeve.

Numerical control turn-milling is compound with automatic receiver, wherein, can dismantle in the drive shaft and be provided with first bevel gear, be provided with on the output shaft with first bevel gear meshed's second bevel gear.

The utility model discloses a numerical control turn-milling is compound with automatic receiver, wherein, be provided with the mounting panel on the first output shaft cover, run through on the mounting panel and be provided with the second rolling bearing who rotates the installation output shaft; and the second output shaft sleeve is fixedly connected with the outer ring of the second rotating bearing or the mounting plate.

Numerical control turn-milling is compound with automatic receiver, wherein, first bevel gear is located the mounting panel with between the second bevel gear.

The utility model discloses a numerical control turn-milling is compound with automatic receiver, wherein, be provided with on the second output shaft cover with the second external gear of first output gear meshing; a rotating shaft is coaxially fixed on the second output gear and is connected with the material receiving hopper through a second clamping fixing piece; the rotating shaft is rotatably connected with the rotating seat through a third rotating bearing.

According to the automatic material receiver for the numerical control turn-milling compounding, the implementation method comprises the following steps:

before or after the receiving hopper receives materials, the power input assembly operates to drive a first output shaft sleeve on a bearing seat to rotate, the first output shaft sleeve drives a gear box body to rotate, the gear box body can drive a rotating seat to rotate while rotating, and the rotating seat rotates to drive the receiving hopper to rotate along a set first direction;

meanwhile, the gear box body rotates to enable the driving shaft and the output shaft to rotate relatively, and the driving shaft does not move, so that the output shaft is driven to rotate in reverse, the output shaft rotates to drive the rotating seat to rotate, and the rotating seat rotates to drive the material receiving hopper to rotate along a set second direction;

simultaneously, it can make second output axle sleeve and first output gear rotate relatively to rotate the seat, and second output axle sleeve is motionless, then can drive first output gear in return and rotate, and first output gear drives second output gear and rotates, and second output gear drives and connects the hopper to rotate along the third direction of settlement.

The beneficial effects of the utility model reside in that: before or after the receiving hopper receives materials, the power input assembly operates to drive a first output shaft sleeve on a bearing seat to rotate, the first output shaft sleeve drives a gear box body to rotate, the gear box body can drive a rotating seat to rotate while rotating, and the rotating seat rotates to drive the receiving hopper to rotate along a set first direction; meanwhile, the gear box body rotates to enable the driving shaft and the output shaft to rotate relatively, and the driving shaft does not move, so that the output shaft is driven to rotate in reverse, the output shaft rotates to drive the rotating seat to rotate, and the rotating seat rotates to drive the material receiving hopper to rotate along a set second direction; meanwhile, the rotation of the rotating seat can enable the second output shaft sleeve and the first output gear to relatively rotate, and the second output shaft sleeve is not moved, so that the first output gear can be driven to rotate in reverse, the first output gear drives the second output gear to rotate, and the second output gear drives the material receiving hopper to rotate along a set third direction; rational in infrastructure and very compact, small, the rotation output of the three direction of butt joint hopper just can be realized to single input, in addition, can also set for the drive ratio between each transmission as required and obtain the rotation angle that wants, and the stroke of connecing the blowing is great.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the present invention will be further described below with reference to the accompanying drawings and embodiments, wherein the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained without inventive work according to the drawings:

FIG. 1 is a schematic view of an expanded structure of an automatic material receiver for numerical control turning and milling according to a preferred embodiment of the present invention;

FIG. 2 is a schematic view of a retracting structure of an automatic material receiver for the combination of the numerical control turning and milling machine according to the preferred embodiment of the present invention;

FIG. 3 is a schematic view of the inside of the automatic material receiver for numerical control turning and milling according to the preferred embodiment of the present invention;

fig. 4 is an exploded view of the automatic material receiver for the combination of the numerical control turning and milling machine according to the preferred embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, a clear and complete description will be given below with reference to the technical solutions of the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

The utility model discloses a numerical control turn-milling composite automatic material receiver of the preferred embodiment, as shown in fig. 1, refer to fig. 2-4 at the same time, including bearing frame 1 and receiving hopper 2, the bearing frame 1 is connected with the first output shaft sleeve 40 and the power input component 3 driving the first output shaft sleeve 40 to rotate in a rotating way; a gear box body 4 is fixed on the first output shaft sleeve 40, a driving shaft 10 extending into the gear box body is fixedly arranged on the bearing seat 1, and the driving shaft 10 coaxially penetrates through the first output shaft sleeve 40; an output shaft 41 is rotatably connected to the gear box body 4, the output shaft 41 is driven by the driving shaft 10 to rotate, and a rotating seat 5 is fixedly connected to the output shaft 41; a second output shaft sleeve 42 sleeved on the output shaft 41 is fixedly arranged on the gear box body 4; the rotating seat 5 is rotatably provided with a first output gear 50 driven by the second output shaft sleeve 42 to rotate and a second output gear 51 driven by the first output gear 50 to rotate, and the receiving hopper 2 is driven by the second output gear 51 to rotate to perform receiving and discharging actions;

before or after the receiving hopper 2 receives materials, the power input assembly 3 operates to drive the first output shaft sleeve 40 on the bearing seat 1 to rotate, the first output shaft sleeve 40 drives the gear box body 4 to rotate, the gear box body 4 can drive the rotating seat 5 to rotate while rotating, and the rotating seat 5 drives the receiving hopper 2 to rotate along a set first direction;

meanwhile, the gear box body 4 rotates to enable the driving shaft 10 and the output shaft 41 to rotate relatively, and the driving shaft 10 does not move, so that the output shaft 41 is driven to rotate in reverse, the rotation of the output shaft 41 drives the rotating seat 5 to rotate, and the rotating seat 5 rotates to drive the material receiving hopper 2 to rotate along a set second direction;

meanwhile, the rotation of the rotating base 5 can make the second output shaft sleeve 42 and the first output gear 50 rotate relatively, and the second output shaft sleeve 42 does not move, which in turn can drive the first output gear 50 to rotate, the first output gear 50 drives the second output gear 51 to rotate, and the second output gear 51 drives the receiving hopper 2 to rotate along a set third direction;

the structure is reasonable and compact, the volume is small, the rotation output in three directions of the butt joint hopper can be realized through single input, in addition, the transmission ratio among all transmissions can be set according to the requirement to obtain the desired rotation angle, and the stroke of receiving and discharging materials is large;

it should be noted that, it can be understood that, the receiving hopper of this application can also be replaced to the instrument of different occasions of application such as anchor clamps, welding tool to realize the multi-angle removal effect, all belong to this application scope of protection based on the simple replacement of this kind of form.

Preferably, the power input assembly 3 comprises a driving cylinder 30, and a power input shaft 31 is connected to the movable end of the driving cylinder 30; the power input shaft 31 is provided with a strip-shaped tooth socket 310; a first external gear 400 matched with the strip-shaped tooth groove 310 is coaxially fixed on the first output shaft sleeve 40; the structure is reasonable and compact, the stability is good, the input and the output are easy to control, and the cost is low.

Preferably, the bearing seat 1 comprises a housing 11, and the housing 11 is provided with an opening for the power input shaft 31 to extend into and a linear bearing 110 for guiding the power input shaft; the shell 11 is fixedly connected with the shell of the driving cylinder 30 through a fixing plate 6; the stability of the output of the power input shaft 31 is ensured, and the integral strength is ensured at the same time.

Preferably, a first clamping and fixing part 111 for clamping and fixing the driving shaft 10 is arranged in the shell 11 or on the shell 11; the assembly is convenient.

Preferably, a first rotation bearing 100 is rotatably connected to the outside of the driving shaft 10; the inner wall of the first output shaft sleeve 40 is provided with a support block (not shown in the figure) for supporting the outer ring of the first rotary bearing 100, and a movable piece 401 which is matched with the support block and clamps and fixes the outer ring of the first rotary bearing 100; the movable plate 401 is detachably connected with the first output shaft sleeve 100; the outer ring of the first rotating bearing is clamped and fixed through the supporting block and the movable sheet on the first output shaft sleeve, the rotating connection assembly effect is achieved, the structure is enabled to become very compact, the size is small, and the protection performance of the first rotating bearing is very strong.

Preferably, the driving shaft 10 is detachably provided with a first bevel gear 101, and the output shaft 41 is provided with a second bevel gear 410 engaged with the first bevel gear; is convenient for transmission and reversing, and has good stability.

Preferably, the first output shaft sleeve 40 is provided with a mounting plate 402, and the mounting plate 402 is provided with a second rotary bearing 403 for rotatably mounting the output shaft 41; the second output shaft sleeve 42 is fixedly connected with the outer ring of the second rotary bearing 403 or the mounting plate 402; convenient assembling, rational and compact structure, good stability and high precision.

Preferably, the first bevel gear 101 is located between the mounting plate 402 and the second bevel gear 410; the structure is reasonable in layout, high in space utilization rate, small in size and good in stability.

Preferably, the second output shaft sleeve 42 is provided with a second external gear 420 engaged with the first output gear; a rotating shaft 510 is coaxially fixed on the second output gear 51, and the rotating shaft 510 is connected with the receiving hopper 2 through a second clamping fixing piece 511; the rotating shaft 510 is rotatably connected with the rotating base 5 through a third rotating bearing 512; convenient assembling, rational and compact structure, good stability and high precision.

meanwhile, the rotation of the rotating seat can enable the second output shaft sleeve and the first output gear to relatively rotate, and the second output shaft sleeve is not moved, so that the first output gear can be driven to rotate in reverse, the first output gear drives the second output gear to rotate, and the second output gear drives the material receiving hopper to rotate along a set third direction;

it should be noted that, it can be understood that the receiving hopper of the above method can also be replaced by a tool such as a clamp, a welding tool, etc. applied to different occasions to achieve the multi-angle moving effect, and simple replacement based on this form is all within the scope of protection of the present application.

It will be understood that modifications and variations can be made by persons skilled in the art in light of the above teachings and all such modifications and variations are considered to be within the scope of the invention as defined by the following claims.

Claims

1. The automatic material receiver for the numerical control turning and milling combination is characterized by comprising a bearing seat and a material receiving hopper, wherein the bearing seat is rotatably connected with a first output shaft sleeve and a power input assembly for driving the first output shaft sleeve to rotate; a gear box body is fixed on the first output shaft sleeve, a driving shaft extending into the gear box body is fixedly arranged on the bearing seat, and the driving shaft coaxially penetrates through the first output shaft sleeve; an output shaft is rotatably connected to the gear box body, the output shaft is driven by the driving shaft to rotate, and a rotating seat is fixedly connected to the output shaft; a second output shaft sleeve sleeved on the output shaft is fixedly arranged on the gear box body; the rotating seat is rotatably provided with a first output gear driven by the second output shaft sleeve to rotate and a second output gear driven by the first output gear to rotate, and the material receiving hopper is driven by the second output gear to rotate to perform material receiving and discharging actions.

2. The automatic material receiver for the numerical control turning and milling combination according to claim 1, characterized in that the power input assembly comprises a driving cylinder, and a movable end of the driving cylinder is connected with a power input shaft; the power input shaft is provided with a strip-shaped tooth socket; and a first external gear matched with the strip-shaped tooth socket is coaxially fixed on the first output shaft sleeve.

3. The automatic material receiver for the numerically controlled turning and milling combination according to claim 2, wherein the bearing housing comprises a housing, and the housing is provided with an opening for the power input shaft to extend into and a linear bearing for guiding the power input shaft; the shell and the shell of the driving cylinder are fixedly connected through a fixing plate.

4. The automatic material receiver for the CNC turning and milling combination according to claim 3, wherein a first clamping and fixing member for clamping and fixing the driving shaft is provided in or on the housing.

5. The automatic material receiver for the CNC turning and milling combination according to any one of claims 1 to 4, wherein a first rotating bearing is rotatably connected to the outside of the driving shaft; the inner wall of the first output shaft sleeve is provided with a supporting block for supporting the outer ring of the first rotating bearing and a movable sheet which is matched with the supporting block and clamps and fixes the outer ring of the first rotating bearing; the movable sheet is detachably connected with the first output shaft sleeve.

6. The automatic material receiver for the numerical control turn-milling combination according to any one of claims 1 to 4, characterized in that a first bevel gear is detachably provided on the driving shaft, and a second bevel gear engaged with the first bevel gear is provided on the output shaft.

7. The automatic material receiver for the numerical control turning and milling combination as claimed in claim 6, wherein a mounting plate is provided on the first output shaft sleeve, and a second rotary bearing for rotatably mounting the output shaft is provided on the mounting plate in a penetrating manner; and the second output shaft sleeve is fixedly connected with the outer ring of the second rotating bearing or the mounting plate.

8. The automatic receiver for numerically controlled turn-milling composite according to claim 7, wherein the first bevel gear is located between the mounting plate and the second bevel gear.

9. The automatic material receiver for the numerically controlled turn-milling combination according to claim 7, wherein a second external gear meshed with the first output gear is provided on the second output shaft sleeve; a rotating shaft is coaxially fixed on the second output gear and is connected with the material receiving hopper through a second clamping fixing piece; the rotating shaft is rotatably connected with the rotating seat through a third rotating bearing.