CN115229630B

CN115229630B - Aluminum alloy casting blank chip milling device

Info

Publication number: CN115229630B
Application number: CN202210771671.2A
Authority: CN
Inventors: 葛修鲁; 韩允; 陆潇
Original assignee: Xuzhou Baitong Aluminum Co ltd
Current assignee: Xuzhou Baitong Aluminum Co ltd
Priority date: 2022-06-30
Filing date: 2022-06-30
Publication date: 2023-11-14
Anticipated expiration: 2042-06-30
Also published as: CN115229630A

Abstract

The application discloses an aluminum alloy casting blank chip milling device, which comprises a driving assembly, a driving mechanism and a chip milling mechanism, wherein the driving assembly comprises a holding part and a driving motor positioned in the holding part, the driving motor is connected with a driving shaft, and the tail end of the driving shaft extends out of the holding part; the polishing device comprises a driving shaft, a polishing wheel and a polishing device, wherein the driving shaft is arranged in the polishing wheel, the polishing wheel is provided with a first through hole penetrating along the axial direction, and the driving shaft is embedded in the first through hole; when the polishing wheel is installed or detached, the adjusting shaft is only pressed, so that the adjusting shaft is driven to rotate, and each part is further linked, so that the effect of quickly replacing the polishing wheel is achieved.

Description

Aluminum alloy casting blank chip milling device

Technical Field

The application relates to the field of metal polishing, in particular to an aluminum alloy casting blank chip milling device.

Background

With the development and progress of society, the requirement on processing automation is higher and higher, the grinder is one of the equipment of main processing, and its main use work piece polishing processing, and degree of automation is often lower in the dish class work piece polishing processing process, has neglected the consumption of emery wheel itself, and a grinder uses, can appear polishing surface pit in the short time, is unfavorable for later operation, consequently in polishing process, need often change emery wheel (polishing wheel), and current change process is more loaded down with trivial details, consuming time and consuming effort, influences polishing efficiency.

Disclosure of Invention

This section is intended to summarize some aspects of embodiments of the application and to briefly introduce some preferred embodiments, which may be simplified or omitted in this section, as well as the description abstract and the title of the application, to avoid obscuring the objects of this section, description abstract and the title of the application, which is not intended to limit the scope of this application.

The present application has been made in view of the above and/or problems occurring in the prior art.

Therefore, the technical problem to be solved by the application is that the grinding wheel (polishing wheel) needs to be replaced frequently in the polishing process, and the existing replacement process is complex, time-consuming and labor-consuming, and affects the polishing efficiency.

In order to solve the technical problems, the application provides the following technical scheme: the aluminum alloy casting blank chip milling device comprises a driving assembly, a driving assembly and a chip milling device, wherein the driving assembly comprises a holding part and a driving motor positioned in the holding part, the driving motor is connected with a driving shaft, and the tail end of the driving shaft extends out of the holding part; the polishing wheel is provided with a first through hole penetrating through the polishing wheel along the axial direction, and the driving shaft is embedded into the first through hole.

As a preferable scheme of the aluminum alloy casting blank milling device, the application comprises the following steps: the one end that is close to of first through-hole the portion of gripping is provided with the spacing groove, the spacing groove is the polygon hole, the drive shaft outside be provided with spacing boss that the spacing groove corresponds to.

As a preferable scheme of the aluminum alloy casting blank milling device, the application comprises the following steps: the end face of the driving shaft is provided with at least two first cylindrical grooves which are uniformly distributed along the circumference, a rotating column is arranged in the first cylindrical grooves, one end of the rotating column, which extends out of the first cylindrical grooves, is provided with a stop block, and the stop block extends outwards along the radial direction from the side face of the rotating column.

As a preferable scheme of the aluminum alloy casting blank milling device, the application comprises the following steps: the driving shaft is internally provided with a long hole extending along the axial direction, the side surface of the long hole penetrates through the side surface of the first cylindrical groove, one end of the long hole, far away from the stop block, extends along the axial direction to form a second cylindrical groove, a moving part is arranged in the second cylindrical groove, the moving part is positioned in the long hole and connected with a strip-shaped block, two ends of the strip-shaped block are respectively provided with a second through hole, the surface of the rotating column is provided with an annular groove, and an entity formed by the second through holes is embedded in the annular groove.

As a preferable scheme of the aluminum alloy casting blank milling device, the application comprises the following steps: the end face of the long hole, which is far away from the moving piece, is connected with a fixed ring, and the side face of the fixed ring is provided with a first round table along the axial direction; the rotary column surface is provided with a guide groove extending along the axial direction, one end of the guide groove, which is close to the moving part, is connected with a chute, the chute extends along the trend of the spiral line, and the first round platform is embedded into the guide groove or the chute.

As a preferable scheme of the aluminum alloy casting blank milling device, the application comprises the following steps: a first spring is arranged between the strip-shaped block and the fixing ring.

As a preferable scheme of the aluminum alloy casting blank milling device, the application comprises the following steps: the movable piece is provided with a third through hole which penetrates through the movable piece, an adjusting cylinder is arranged in the third through hole, a first spiral groove is formed in the outer side face of the adjusting cylinder, a second round table is arranged on the inner side wall of the third through hole, and the second round table is embedded into the first spiral groove; an annular boss is arranged in the second cylindrical groove, a check ring is arranged at the end part of the adjusting cylinder, and the check ring is in contact with the end face of the annular boss.

As a preferable scheme of the aluminum alloy casting blank milling device, the application comprises the following steps: the end part of the driving shaft is also provided with a fourth through hole penetrating through the long hole, an adjusting shaft is arranged in the driving shaft, one end of the adjusting shaft penetrates through the fourth through hole, and the other end of the adjusting shaft is embedded into the adjusting cylinder; the adjusting cylinder is provided with a fifth through hole, the inner side surface of the fifth through hole is provided with a second spiral groove, the adjusting shaft is provided with a third round table, the third round table is embedded into the second spiral groove, and the rotation direction of the second spiral groove is opposite to that of the first spiral groove;

the part of the adjusting shaft positioned in the long hole is provided with a limiting shaft shoulder.

As a preferable scheme of the aluminum alloy casting blank milling device, the application comprises the following steps: one end of the adjusting shaft, which passes through the fifth through hole, is provided with a limiting round table, the end surface of the limiting round table, which is close to the check ring, is provided with limiting convex strips which are uniformly distributed along the circumference, and the check ring is provided with limiting grooves corresponding to the limiting convex strips.

As a preferable scheme of the aluminum alloy casting blank milling device, the application comprises the following steps: and a second spring is arranged between the bottom of the second cylinder and the limiting round table.

The application has the beneficial effects that: when the polishing wheel is installed or detached, the adjusting shaft is only pressed, so that the adjusting shaft is driven to rotate, and each part is further linked, so that the effect of quickly replacing the polishing wheel is achieved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

fig. 1 is a schematic structural diagram of an aluminum alloy casting blank chip milling device according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a driving assembly in an aluminum alloy casting blank milling device according to an embodiment of the present application;

fig. 3 is a schematic structural diagram of a rotary column 104 in an aluminum alloy casting blank milling device according to an embodiment of the present application;

fig. 4 is a schematic structural view of an adjusting cylinder 108 in an aluminum alloy casting blank milling device according to an embodiment of the present application;

fig. 5 is an exploded schematic view of an aluminum alloy casting blank milling device according to an embodiment of the present application;

fig. 6 is a schematic cross-sectional structure of a driving assembly in an aluminum alloy casting blank milling device according to an embodiment of the present application.

In the figure: a drive assembly 100; a grip 101; a drive motor 102; a drive shaft 103; polishing wheel 200; a first through hole 201; a first limit groove 201a; a limit boss 103a; a first cylindrical groove 103b; rotating the column 104; a stopper 104a; a long hole 103c; a second cylindrical groove 103d; a mover 105; a bar 105b; a second through hole 105c; annular groove 104b; a securing ring 106; a first round table 106a; a guide groove 104c; a chute 104d; a first spring 107; a third through hole 105a; an adjustment cylinder 108; a first spiral groove 108a; a second round table 105d; an annular boss 103e; a retainer ring 108b; a limit ring groove 103h; a fourth through hole 103f; an adjustment cylinder 108; a second spiral groove 108d; a third round table 109a; a limit shoulder 109b; 103g of a limiting long groove; a limit bar 109e; a limit round table 109c; a second limit groove 108e; a second spring 109f.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

Examples

Referring to fig. 1-6, the embodiment provides an aluminum alloy casting blank chip milling device, which comprises a driving assembly 100 and a polishing wheel 200, wherein the driving assembly 100 comprises a holding part 101 and a driving motor 102 positioned in the holding part 101, the holding part 101 and the driving motor 102 are both in the prior art, the driving motor 102 is connected with a driving shaft 103, and the tail end of the driving shaft 103 extends out of the holding part 101; the grip 101 is easy to hold and the drive motor 102 provides power. The polishing wheel 200 is a grinding wheel or other wheel with buffing and polishing, the polishing wheel 200 is provided with a first through hole 201 penetrating along the axial direction, and the driving shaft 103 is embedded in the first through hole 201. Therefore, when the polishing wheel 200 is driven to rotate at a high speed, the aluminum alloy material can be polished.

Further, a first limiting groove 201a is disposed at one end of the first through hole 201 near the holding portion 101, the first limiting groove 201a is a polygonal hole, in this embodiment, the first limiting groove 201a is a hexagonal hole, a limiting boss 103a corresponding to the first limiting groove 201a is disposed outside the driving shaft 103, and the limiting boss 103a is a hexagonal prism, so that the driving shaft 103 and the polishing wheel cannot rotate relatively due to cooperation of the first limiting groove 201a and the limiting boss 103 a.

The end face of the driving shaft 103 is provided with at least two first cylindrical grooves 103b uniformly distributed along the circumference, in this embodiment, the first cylindrical grooves 103b are provided with two rotating columns 104, the rotating columns 104 can rotate or axially move in the first cylindrical grooves 103b, one end of the rotating columns 104 extending out of the first cylindrical grooves 103b is provided with a stop block 104a, and the stop block 104a extends outwards along the radial direction from the side face of the rotating columns 104. Therefore, when the end of the driving shaft 103 is embedded into the first through hole 201, the first limit groove 201a is matched with the limit boss 103a, and at this time, the rotating column 104 is rotated to position the stop block 104a at the outer edge of the first through hole 201, and then the stop block 104a is tightly attached to the outer end surface of the first through hole 201, i.e. the rotating column 104 is moved in the axial direction, so that the stop block 104a can press the polishing wheel 200, and the fixing of the polishing wheel 200 can be completed.

Further, a long hole 103c extending along the axial direction is arranged in the driving shaft 103, and the side surface of the long hole 103c penetrates through the side surface of the first cylindrical groove 103b, namely, the length of the axis of the long hole 103c from the axis of the first cylindrical groove 103b is smaller than the length of the radius of the long hole 103c plus the radius of the first cylindrical groove 103b; an end of the long hole 103c remote from the stopper 104a extends in the axial direction to form a second cylindrical groove 103d, and the diameter of the second cylindrical groove 103d is smaller than the diameter of the long hole 103 c.

The movable piece 105 is arranged in the second cylindrical groove 103d, the movable piece 105 is cylindrical and can axially move in the second cylindrical groove 103d, the movable piece 105 is located in the long hole 103c and is connected with the bar-shaped blocks 105b, two ends of the bar-shaped blocks 105b respectively extend into the two first cylindrical grooves 103b, two ends of the bar-shaped blocks 105b are respectively provided with a second through hole 105c, annular grooves 104b are formed in the surfaces of the rotating columns 104, and entities formed by the second through holes 105c are embedded into the annular grooves 104 b. And the width of the annular groove 104b coincides with the thickness of the bar 105b, the rotation column 104 can be controlled by the moving member 105.

The end face of the long hole 103c far away from the moving piece 105 is connected with a fixed ring 106, the fixed ring 106 and the inside of the driving shaft 103 are integrally formed, and the side face of the fixed ring 106 is provided with a first round table 106a along the axial direction; the surface of the rotating column 104 is provided with a guide groove 104c extending along the axial direction, one end, close to the moving piece 105, of the guide groove 104c is connected with a chute 104d, the chute 104d extends along the trend of a spiral line, and the first round table 106a is embedded into the guide groove 104c or the chute 104 d. Therefore, when the first round table 106a is located in the guide groove 104c, the moving member 105 will drive the rotating column 104 to move linearly along the axial direction, when the first round table 106a is located in the inclined groove 104d, the moving member 105 moves linearly, so that the inclined groove 104d moves along the position of the first round table 106a, therefore, the rotating column 104 moves spirally, when the first round table 106a is located at the extreme end of the inclined groove 104d, namely, the farthest from the guide groove 104c, the distance between the stop block 104a and the end face of the driving shaft 103 is also the farthest, the stop block 104a is also located in the transverse outline of the driving shaft 103, the polishing wheel 200 can be mounted or dismounted, when the polishing wheel 200 is mounted at a specified position, the moving member 105 is operated to move away from the polishing wheel 200, the moving member 105 moves along the rotating column 104, so that the first round table 106a moves from the position located at the extreme end of the inclined groove 104d to the junction of the inclined groove 104d and the guide groove 104c, at the moment, the stop block 104a rotates to the inner and outer side of the driving shaft 103, and then presses the polishing wheel 200 again along the moving block 104a transversely along the transverse outline of the guide groove 104 c.

Preferably, a first spring 107 is provided between the bar 105b and the fixing ring 106. The first spring 107 is a pressure spring, and can prevent the bar 105b from approaching the fixing ring 106.

Further, the moving member 105 is provided with a third through hole 105a penetrating through, an adjusting cylinder 108 is arranged in the third through hole 105a, a first spiral groove 108a is formed in the outer side surface of the adjusting cylinder 108, a second round table 105d is arranged on the inner side wall of the third through hole 105a, and the second round table 105d is embedded in the first spiral groove 108a; an annular boss 103e is arranged in the second cylindrical groove 103d, a check ring 108b is arranged at the end part of the adjusting cylinder 108, the check ring 108b is in end surface contact with the annular boss 103e, a limit annular groove 103h is arranged in the second cylindrical groove 103d, and the check ring 108b is embedded into the limit annular groove 103 h. The cooperation of the limit ring groove 103h, the retainer ring 108b and the annular boss 103e enables the adjustment cylinder 108 to rotate in the third through hole 105a but not move along the axial direction, and the rotation of the adjustment cylinder 108 enables the second round table 105d to move in cooperation with the first spiral groove 108a, so that the rotation of the adjustment cylinder 108 is converted into the linear motion of the second round table 105 d.

The end part of the driving shaft 103 is also provided with a fourth through hole 103f penetrating through the long hole 103c, the driving shaft 103 is internally provided with an adjusting shaft 109, one end of the adjusting shaft 109 penetrates through the fourth through hole 103f, and the other end of the adjusting shaft 109 is embedded into the adjusting cylinder 108; the adjusting cylinder 108 is provided with a fifth through hole 108c, the inner side surface of the fifth through hole 108c is provided with a second spiral groove 108d, the adjusting shaft 109 is provided with a third round platform 109a, the third round platform 109a is embedded into the second spiral groove 108d, and the rotation direction of the second spiral groove 108d is opposite to that of the first spiral groove 108a; the third circular table 109a cooperates with the second spiral groove 108d such that the linear movement of the adjustment shaft 109 is converted into a rotation of the adjustment cylinder 108, and the movement direction of the adjustment shaft 109 is always opposite to the movement direction of the moving member 105 during the transmission because the second spiral groove 108d is opposite to the rotation direction of the first spiral groove 108 a.

Wherein, the part of the adjusting shaft 109 in the long hole 103c is provided with a limiting shaft shoulder 109b, and the diameter of the limiting shaft shoulder 109b is larger than the inner diameter of the fourth through hole 103f, so as to prevent the adjusting shaft 109 from completely falling off.

Preferably, a limiting long groove 103g along the axial direction is arranged on the side surface of the fourth through hole 103f, a limiting strip 109e is arranged at the part of the adjusting shaft 109 positioned in the fourth through hole 103f, and the limiting strip 109e is embedded in the limiting long groove 103 g. The cooperation of the limiting strip 109e and the limiting long groove 103g makes the adjusting shaft 109 only move linearly along the axis and not rotate.

One end of the adjusting shaft 109, which passes through the fifth through hole 108c, is provided with a limiting round platform 109c, the end surface of the limiting round platform 109c, which is close to the check ring 108b, is provided with a limiting convex strip 109d which is uniformly distributed along the circumference, and the check ring 108b is provided with a second limiting groove 108e which corresponds to the limiting convex strip 109 d. In a state of fixing the polishing wheel 200, the limit protruding strips 109d are embedded into the second limit grooves 108e to form a self-locking structure, so that the adjustment cylinder 108 is prevented from being circumferentially offset.

Preferably, a second spring 109f is disposed between the bottom of the second slot 103d and the limiting boss 109 c. The second spring 109f is a pressure spring, and after the polishing wheel 200 is fixed, the elastic force pushes the adjustment shaft 109 to prevent loosening.

In this embodiment, in the initial state, the first round table 106a is located in the guide groove 104c, and the stopper 104a is located outside the driving shaft 103; when the polishing wheel 200 is mounted or dismounted, the adjusting shaft 109 is pressed to drive the adjusting cylinder 108 to rotate, the adjusting cylinder 108 drives the moving member 105, the moving member 105 drives the rotating column 104, the first round table 106a is positioned in the chute 104d and is positioned at the end of the chute 104d, the polishing wheel 200 is mounted, at this time, the polishing wheel 200 is placed at a fixed position, the first limit groove 201a is matched with the limit boss 103a, then the adjusting shaft 109 is slowly loosened, the chute 104d and the first round table 106a act, so that the stop block 104a turns to and approaches the polishing wheel 200, when the first round table 106a moves relatively in the guide groove 104c, the stop block 104a presses and the polishing wheel 200, and meanwhile, the limit protruding strip 109d is embedded in the second limit groove 108e to form a self-locking structure, so that the fixing effect is enhanced, and when the adjusting shaft 109 is pressed during dismounting, the limit protruding strip 109d is naturally separated from the second limit groove 108e.

It should be noted that the above embodiments are only for illustrating the technical solution of the present application and not for limiting the same, and although the present application has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present application may be modified or substituted without departing from the spirit and scope of the technical solution of the present application, which is intended to be covered in the scope of the claims of the present application.

Claims

1. An aluminum alloy casting blank milling scraps device which is characterized in that: comprising the steps of (a) a step of,

the driving assembly (100) comprises a holding part (101) and a driving motor (102) positioned in the holding part (101), wherein the driving motor (102) is connected with a driving shaft (103), and the tail end of the driving shaft (103) extends out of the holding part (101);

a polishing wheel (200), wherein the polishing wheel (200) is provided with a first through hole (201) penetrating along the axial direction, and the driving shaft (103) is embedded in the first through hole (201);

a first limit groove (201 a) is formed in one end, close to the holding part (101), of the first through hole (201), the first limit groove (201 a) is a polygonal hole, and a limit boss (103 a) corresponding to the first limit groove (201 a) is arranged outside the driving shaft (103);

the end face of the driving shaft (103) is provided with at least two first cylindrical grooves (103 b) which are uniformly distributed along the circumference, a rotating column (104) is arranged in the first cylindrical grooves (103 b), one end of the rotating column (104) extending out of the first cylindrical grooves (103 b) is provided with a stop block (104 a), and the stop block (104 a) extends outwards from the side face of the rotating column (104) along the radial direction;

the driving shaft (103) is internally provided with a long hole (103 c) extending along the axial direction, the side surface of the long hole (103 c) penetrates through the side surface of the first cylindrical groove (103 b), one end, far away from the stop block (104 a), of the long hole (103 c) extends along the axial direction to form a second cylindrical groove (103 d), a moving piece (105) is arranged in the second cylindrical groove (103 d), the moving piece (105) is positioned in the long hole (103 c) and connected with a strip-shaped block (105 b), two ends of the strip-shaped block (105 b) are respectively provided with a second through hole (105 c), an annular groove (104 b) is formed on the surface of the rotating column (104), and a solid formed by the second through holes (105 c) is embedded in the annular groove (104 b);

the end face of the long hole (103 c) far away from the moving piece (105) is connected with a fixed ring (106), and a first round table (106 a) along the axial direction is arranged on the side face of the fixed ring (106); the surface of the rotating column (104) is provided with a guide groove (104 c) extending along the axial direction, one end, close to the moving part (105), of the guide groove (104 c) is connected with a chute (104 d), the chute (104 d) extends along the trend of a spiral line, and the first round table (106 a) is embedded into the guide groove (104 c) or the chute (104 d);

a first spring (107) is arranged between the strip-shaped block (105 b) and the fixed ring (106);

the movable piece (105) is provided with a third through hole (105 a) which penetrates through, an adjusting cylinder (108) is arranged in the third through hole (105 a), a first spiral groove (108 a) is formed in the outer side face of the adjusting cylinder (108), a second round table (105 d) is arranged on the inner side wall of the third through hole (105 a), and the second round table (105 d) is embedded into the first spiral groove (108 a); an annular boss (103 e) is arranged in the second cylindrical groove (103 d), a retainer ring (108 b) is arranged at the end part of the adjusting cylinder (108), and the retainer ring (108 b) is in end surface contact with the annular boss (103 e); a limiting ring groove (103 h) is formed in the second cylinder groove (103 d), and a retainer ring (108 b) is embedded into the limiting ring groove (103 h);

the end part of the driving shaft (103) is also provided with a fourth through hole (103 f) penetrating through the long hole (103 c), an adjusting shaft (109) is arranged in the driving shaft (103), one end of the adjusting shaft (109) penetrates through the fourth through hole (103 f), and the other end of the adjusting shaft is embedded into the adjusting cylinder (108); the adjusting cylinder (108) is provided with a fifth through hole (108 c), the inner side surface of the fifth through hole (108 c) is provided with a second spiral groove (108 d), the adjusting shaft (109) is provided with a third round table (109 a), the third round table (109 a) is embedded into the second spiral groove (108 d), and the rotation direction of the second spiral groove (108 d) is opposite to that of the first spiral groove (108 a);

a limiting shaft shoulder (109 b) is arranged at the part of the adjusting shaft (109) positioned in the long hole (103 c), a limiting long groove (103 g) along the axial direction is arranged at the side surface of the fourth through hole (103 f), a limiting strip (109 e) is arranged at the part of the adjusting shaft (109) positioned in the fourth through hole (103 f), and the limiting strip (109 e) is embedded into the limiting long groove (103 g);

one end of the adjusting shaft (109) penetrating through the fifth through hole (108 c) is provided with a limiting round table (109 c), the end face, close to the check ring (108 b), of the limiting round table (109 c) is provided with limiting convex strips (109 d) which are uniformly distributed along the circumference, and the check ring (108 b) is provided with second limiting grooves (108 e) corresponding to the limiting convex strips (109 d).

2. The aluminum alloy casting blank chip milling device according to claim 1, wherein: a second spring (109 f) is arranged between the bottom of the second cylinder (103 d) and the limiting round table (109 c).