CN217777413U

CN217777413U - Cutter lifting mechanism for quartz wafer cutting machine

Info

Publication number: CN217777413U
Application number: CN202221478040.3U
Authority: CN
Inventors: 叶竹之; 李辉; 宋嵩; 刘屿剑
Original assignee: Chengdu Timemaker Crystal Technology Co ltd
Current assignee: Chengdu Timemaker Crystal Technology Co ltd
Priority date: 2022-06-14
Filing date: 2022-06-14
Publication date: 2022-11-11
Anticipated expiration: 2032-06-14

Abstract

The utility model discloses a cutter elevating system for quartz wafer cutting machine relates to quartz wafer cutting machine technical field, include: the device comprises a machine body 1 and a motor 2 arranged on one side of the outer wall of the machine body 1; cutting the steel wire 7; a linkage unit 8 having a linkage post 802; and a locking unit 9. The utility model discloses a set up linkage unit 8, when needs carry out the rate of tension to cutting steel wire 7 and adjust, can drive linkage post 802 and use lift seat 801 to reciprocate the operation as the base, linkage post 802 is through rotating sleeve 806, the transmission of gangbar 807 can drive two processing rollers 804 and carry out synchronous horizontal migration, and the moving direction of two processing rollers 804 is opposite state, can realize two processing rollers 804's interval adjustment then, drive the removal of leading row's wheel 805 through processing roller 804, can realize the rate of tension regulation operation to cutting steel wire 7.

Description

Cutter lifting mechanism for quartz wafer cutting machine

Technical Field

The utility model relates to a quartz wafer cutting machine technical field specifically is a cutter elevating system for quartz wafer cutting machine.

Background

The quartz crystal is the largest crystal material in use in the world at present, and electronic components, such as quartz crystal resonators, crystal filters, quartz crystal oscillators and the like, are manufactured by utilizing the physical characteristics of the crystal. The stability characteristic of the quartz crystal at the frequency end can be used as a frequency reference or a frequency source, and the quartz crystal is widely applied to the fields of digital circuits, electronic products and communication equipment. The cutting principle of the wire cutting machine is that a series of grooves with certain depth are parallelly carved on a processing roller according to the cutting width requirement, the steel wire is wound on the grooves to form a metal wire mesh consisting of a plurality of parallel metal wires, the grooves can ensure that the steel wires are always kept parallel and not deviated in the processing process, the motor drives the processing roller to drive the steel wires wound on the processing roller, the steel wires at the processing section move in a unidirectional or unidirectional manner, the conventional silicon wafer wire cutting machine only needs to replace the silicon wafer with different thicknesses due to the fact that the grooves on the processing roller are fixed, and therefore the silicon wafer production cost is reduced.

According to the notice number: CN 112060376A discloses a silicon chip wire cutting machine convenient to adjust, including the base, the top fixed mounting of base has the fuselage, and the top fixed mounting of base has electric putter, and electric putter's top fixed mounting has the workstation, and the inside fixed mounting of workstation has the support frame. This silicon chip wire cut electrical discharge machining convenient to adjust makes T shape screw rod take the toper piece towards the direction motion of keeping away from the volleyball wheel axle center through loosening T shape screw rod, lead to the toper piece to break away from gradually with the contact of ejector pad, at this moment the spring resets and takes ejector pad and spacer pin to move towards the direction of keeping away from the processing roller, until spacer pin and processing roller separation, then just can adjust the distance between two adjacent volleyball wheels through the position of slip volleyball wheel on the processing roller, lead to the winding to follow the regulation in the distance between the cutting steel wire on the volleyball wheel, the advantage that cutting thickness is adjustable has been possessed.

The distance between two adjacent calandria wheels is adjusted through the position of slip calandria wheel on the processing roller in the above-mentioned patent, leads to the winding to follow the regulation in the distance between the cutting steel wire on the calandria wheel to the function with adjustable cutting thickness has been had, but because the rigidity of processing roller when the installation is used, can't adjust the rate of tension of steel wire, has not only influenced the installation of steel wire, and has led to the fact the influence to cutting accuracy afterwards.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a: in order to solve the problem that the wire cutter is not convenient for adjusting the tension degree of a steel wire, the cutter lifting mechanism for the quartz wafer cutter is provided.

In order to achieve the above object, the utility model provides a following technical scheme: a cutter lifting mechanism for a quartz wafer cutting machine, comprising: the automatic winding machine comprises a machine body and a motor arranged on one side of the outer wall of the machine body, wherein a driving gear is arranged at the output end of the motor, driven gears are meshed with two sides of the driving gear, the two driven gears penetrate through the inner side of the machine body through a rotating shaft and are respectively connected with a pay-off roller and a take-up roller, and the take-up roller is positioned at one end of the pay-off roller; the two ends of the cutting steel wire are respectively connected with the pay-off roller and the take-up roller; the linkage unit is provided with a linkage column, is arranged in the machine body main body, extends to the inner side of the machine body main body, is sleeved with the outer wall of the cutting steel wire and is used for adjusting the tension degree of the cutting steel wire; and the locking units are distributed on the inner side of the machine body main body and the outer side of the linkage column and extend to the locking units inside the linkage column, and are used for fixing the position of the linkage column.

As a further aspect of the present invention: the linkage unit further includes: the linkage post is fixed on one side of the lifting seat and extends through the inner side of the machine body main body; the two moving seats are slidably mounted in the machine body main body and located below the lifting seat, the two moving seats are symmetrically distributed by taking the lifting seat as a center, a first telescopic spring is arranged at one end, away from each other, of each moving seat, one side of each moving seat is rotatably connected with a processing roller penetrating to the inner side of the machine body main body, a guide row wheel sleeved with the outer wall of the cutting steel wire is arranged on the outer wall of the processing roller, and a groove matched with the outer wall of the cutting steel wire is formed in the guide row wheel; the outer wall of the linkage column is rotatably connected with two rotating sleeves, the two rotating sleeves on the outer wall of the linkage column are respectively connected with a linkage rod, and the other ends of the linkage rods are respectively connected with the two rotating sleeves on the outer wall of the processing roller.

As the utility model discloses further scheme again: the locking unit includes: the pressing block is arranged on one side, away from the lifting seat, of the linkage column, and a connecting column penetrating into the linkage column is arranged on one side, close to the linkage column, of the pressing block; a locking gear sleeved on the outer wall of the linkage column is rotated, the locking gear is positioned between the rotating sleeve and the lifting seat, and a locking strip is fixedly connected to one end, positioned on the locking gear, of the inner side of the machine body main body; the moving column is arranged in the linkage column and extends into the lifting seat, the moving column is fixedly connected with one side, away from the pressing block, of the connecting column, and a return spring is arranged at one end, away from the connecting column, of the moving column; the setting is in inside and the extension of linkage post runs through to the inside flexible ball of locking gear, flexible ball is located the outside of removing the post, remove the post with annular indent has been seted up to the position of flexible ball contact, it is located to remove the post outside annular indent has been seted up to one side of annular indent and has been accomodate the groove.

As the utility model discloses further scheme again: the inner wall of the machine body main body is provided with a vertical sliding groove matched with the lifting seat, the inner wall of the machine body main body is provided with a transverse sliding groove matched with the moving seat, the number of the guide row wheels is multiple, and the guide row wheels are uniformly distributed on the outer wall of the processing roller.

As a further aspect of the present invention: the number of the telescopic balls is provided with a plurality of telescopic balls, the telescopic balls are distributed in an annular shape by taking the movable column as a center, the inner side of the locking gear is provided with positioning holes matched with the telescopic balls, and the number of the positioning holes is matched with that of the telescopic balls.

As the utility model discloses further scheme again: and a rack meshed with the locking gear is arranged on one side, close to the locking gear, of the locking strip.

As a further aspect of the present invention: the inner wall depth of the annular accommodating groove is larger than that of the annular pressure groove, and the inner wall width of the annular pressure groove is larger than the diameter of the outer wall of the telescopic ball.

Compared with the prior art, the beneficial effects of the utility model are that:

1. by arranging the linkage unit, when the tension of the cutting steel wire is required to be adjusted, the linkage column can be driven to move up and down by taking the lifting seat as a base, the linkage column can drive the two processing rollers to synchronously and horizontally move through the transmission of the rotating sleeve and the linkage rod 7, the moving directions of the two processing rollers are opposite, the distance between the two processing rollers can be adjusted, and the tension of the cutting steel wire can be adjusted by driving the guide row wheel to move through the processing rollers;

2. through setting up the locking unit, promote to pass through the spliced pole according to the briquetting and promote the removal of removal post, and extrude reset spring shrink, the annular on the removal post this moment is accomodate the groove and is aligned with flexible ball, when removing the operation to the linkage post this moment, locking gear can rotate, and form the extrusion to flexible ball and make it shrink to the annular and accomodate the inslot portion, make flexible ball can not influence the rotation of locking gear, thereby be convenient for the removal operation of linkage post, after linkage height confirms, can loosen the pressing according to the briquetting, the briquetting is moved under reset spring's effect this moment, press briquetting automatic re-setting, can make flexible ball accomodate the inslot from the annular and shift out to the annular indent inside when removing the briquetting, flexible ball can follow linkage post inside running through to the locking gear inside this moment, make the locking gear unable rotation, through the rack mutually supporting on locking gear and the locking strip, can make the unable removal of linkage post, thereby realize the locking operation of linkage unit.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a bottom view of the structure of the present invention;

fig. 3 is a schematic structural view of the linkage unit of the present invention;

fig. 4 is a schematic view of the linkage unit and the locking unit according to the present invention;

fig. 5 is a sectional view of the linkage column and the lifting seat of the present invention.

In the figure: 1. a main body of the body; 2. a motor; 3. a driving gear; 4. a driven gear; 5. a pay-off roller; 6. a wire take-up roller; 7. cutting a steel wire; 8. a linkage unit; 801. a lifting seat; 802. a linkage column; 803. a movable seat; 804. processing a roller; 805. a guide row wheel; 806. rotating the sleeve; 807. a linkage rod; 808. a first extension spring; 809. a second extension spring; 9. a locking unit; 901. a locking bar; 902. a lock gear; 903. a pressing block; 904. connecting columns; 905. moving the column; 9051. annular pressure groove; 9052. an annular receiving groove; 906. a return spring; 907. and (4) telescopic balls.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 5, in an embodiment of the present invention, a cutter lifting mechanism for a quartz wafer cutting machine includes: the automatic winding machine comprises a machine body main body 1 and a motor 2 arranged on one side of the outer wall of the machine body main body 1, wherein a driving gear 3 is arranged at the output end of the motor 2, driven gears 4 are meshed with two sides of the driving gear 3, the two driven gears 4 penetrate through the inner side of the machine body main body 1 through rotating shafts and are respectively connected with a pay-off roller 5 and a take-up roller 6, and the take-up roller 6 is positioned at one end of the pay-off roller 5; the two ends of the cutting steel wire 7 are respectively connected with the pay-off roller 5 and the take-up roller 6; the linkage unit 8 is provided with a linkage column 802, is arranged in the machine body 1, extends to the inner side of the machine body 1 and is sleeved with the outer wall of the cutting steel wire 7, and is used for adjusting the tension of the cutting steel wire 7; the locking units 9 are distributed on the inner side of the body 1 and the outer side of the linkage column 802 and extend through the linkage column 802, and are used for fixing the position of the linkage column 802.

In this embodiment: the synchronous syntropy that can realize unwrapping wire roller 5, receive line roller 6 is rotated through the transmission of driving gear 3, driven gear 4 during motor 2 operation to realize the operation of cutting steel wire 7, can adjust the rate of tension of cutting steel wire 7 through linkage unit 8, can effectively improve the cutting accuracy of cutting machine, can carry out the locking to linkage unit 8 through locking unit 9, can improve the operating stability of cutting machine.

Please refer to fig. 1 to 5, the linkage unit 8 further includes: the lifting seat 801 is slidably mounted in the machine body 1, a second telescopic spring 809 is arranged at the bottom end of the lifting seat 801, and the linkage column 802 is fixed at one side of the lifting seat 801 and extends through the inner side of the machine body 1; the two moving seats 803 are slidably mounted in the machine body main body 1 and positioned below the lifting seat 801, the two moving seats 803 are symmetrically distributed by taking the lifting seat 801 as a center, one ends, away from each other, of the two moving seats 803 are provided with first telescopic springs 808, one side of each moving seat 803 is rotatably connected with a processing roller 804 penetrating through the inner side of the machine body main body 1, the outer wall of each processing roller 804 is provided with a guide row wheel 805 sleeved with the outer wall of the cutting steel wire 7, and a groove matched with the outer wall of the cutting steel wire 7 is formed in each guide row wheel 805; the rotating sleeve 806 sleeved on the outer walls of the linkage column 802 and the processing roller 804 is rotated, the outer wall of the linkage column 802 is rotatably connected with two rotating sleeves 806, the two rotating sleeves 806 on the outer wall of the linkage column 802 are respectively connected with a linkage rod 807, and the other ends of the two linkage rods 807 are respectively connected with the rotating sleeves 806 on the outer walls of the two processing rollers 804.

In this embodiment: when the rate of tension adjustment needs to be carried out on the cutting steel wire 7, the position locking to the linkage post 802 can be relieved through the locking unit 9 firstly, then the linkage post 802 can be driven to move up and down by taking the lifting seat 801 as a base, in the process, the linkage post 802 can drive the two processing rollers 804 to carry out synchronous horizontal movement through the transmission of the rotating sleeve 806 and the linkage rod 807, the moving directions of the two processing rollers 802 are opposite, then the interval adjustment of the two processing rollers 802 can be realized, the movement of the guide row wheel 805 is driven through the processing rollers 802, and the rate of tension adjustment operation on the cutting steel wire 7 can be realized.

Referring to fig. 2 to 5, the locking unit 9 includes: the pressing block 903 is arranged on one side, away from the lifting seat 801, of the linkage column 802, and a connecting column 904 penetrating into the linkage column 802 is arranged on one side, close to the linkage column 802, of the pressing block 903; a locking gear 902 sleeved on the outer wall of the linkage column 802 in a rotating mode, the locking gear 902 is located between the rotating sleeve 806 and the lifting seat 801, and a locking strip 901 is fixedly connected to one end, located on the locking gear 902, of the inner side of the machine body 1; the moving column 905 is arranged inside the linkage column 802 and extends into the lifting seat 801, the moving column 905 is fixedly connected with one side, away from the pressing block 903, of the connecting column 904, and a return spring 906 is arranged at one end, away from the connecting column 904, of the moving column 905; the telescopic ball 907 is arranged inside the linkage column 802 and extends into the locking gear 902, the telescopic ball 907 is located on the outer side of the moving column 905, an annular pressing groove 9051 is formed in the position, in contact with the telescopic ball 907, of the moving column 905, and an annular accommodating groove 9052 is formed in one side, located on the annular pressing groove 9051, of the outer side of the moving column 905; one side of the locking bar 901 close to the locking gear 902 is provided with a rack meshed with the locking gear 902; the depth of the inner wall of the annular accommodating groove 9052 is greater than that of the inner wall of the annular pressing groove 9051, and the width of the inner wall of the annular pressing groove 9051 is greater than the diameter of the outer wall of the telescopic ball 907.

In this embodiment: when the linkage column 802 needs to be moved, the pressing block 903 can be pushed to move towards the linkage column 802, the pressing block 903 can push the moving column 905 to move through the connecting column 904 and press the return spring 906 to contract, at this time, the annular accommodating groove 9052 in the moving column 905 is aligned with the telescopic ball 907, at this time, when the linkage column 802 is moved, the locking gear 902 can rotate under the action of the rack on the outer wall of the locking bar 901, when the locking gear 902 rotates, the telescopic ball 907 can be squeezed to be contracted into the annular accommodating groove 9052, the telescopic ball 907 cannot influence the rotation of the locking gear 902, so that the moving operation of the linkage column 802 is facilitated, after the height of the linkage column 802 is determined, the pressing on the pressing block 903 can be released, at this time, the pressing block 905 and the pressing block 903 automatically reset under the action of the return spring 906, when the moving block 905 moves, the telescopic ball 907 can move out from the annular accommodating groove 9052 into the annular pressing groove 9051, at this time, the telescopic ball 907 can penetrate through the inside of the linkage column 802 to the inside of the locking gear 902, at this time, the locking gear cannot rotate with the linkage column 902, so that the linkage column 802 can be moved, and the linkage column 802 can be moved, so that the linkage column 902 can be moved.

Please refer to fig. 2 to 4, the inner wall of the main body 1 is provided with a vertical sliding slot matching with the lifting seat 801, the inner wall of the main body 1 is provided with a horizontal sliding slot matching with the moving seat 803, a plurality of guide rollers 805 are provided, and the plurality of guide rollers 805 are uniformly distributed on the outer wall of the processing roller 804.

In this embodiment: through the structure, the lifting seat 801 can move up and down along the vertical sliding chute, and the moving seat 805 can move left and right horizontally along the transverse sliding chute, so that the movement adjustment operation of the guide row wheels 805 is realized.

Please refer to fig. 5, the number of the retractable balls 907 is plural, the plural retractable balls 907 are distributed in a ring shape with the moving column 905 as the center, the inner side of the locking gear 902 is provided with positioning holes matched with the retractable balls 907, and the number of the positioning holes is matched with the retractable balls 907.

In this embodiment: the fixed locking operation of the locking gear 902 can be realized through the mutual clamping of the telescopic ball 907 and the positioning hole.

The above-mentioned, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a cutter elevating system for quartz wafer cutting machine which characterized in that includes:

the automatic wire winding machine comprises a machine body main body (1) and a motor (2) arranged on one side of the outer wall of the machine body main body (1), wherein a driving gear (3) is arranged at the output end of the motor (2), driven gears (4) are meshed with two sides of the driving gear (3), the two driven gears (4) penetrate through the inner side of the machine body main body (1) through rotating shafts and are respectively connected with a wire unwinding roller (5) and a wire winding roller (6), and the wire winding roller (6) is located at one end of the wire unwinding roller (5);

the two ends of the cutting steel wire (7) are respectively connected with the pay-off roller (5) and the take-up roller (6);

the linkage unit (8) is provided with a linkage column (802), is arranged in the machine body (1), extends to the inner side of the machine body (1), is sleeved with the outer wall of the cutting steel wire (7), and is used for adjusting the tension of the cutting steel wire (7);

the locking units (9) are distributed on the inner side of the machine body main body (1), the outer side of the linkage column (802) and extend to the inner part of the linkage column (802) in a penetrating mode, and are used for fixing the position of the linkage column (802).

2. The cutter lifting mechanism for a quartz wafer cutting machine according to claim 1, wherein said linkage unit (8) further comprises:

the lifting seat (801) is slidably mounted in the machine body (1), a second telescopic spring (809) is arranged at the bottom end of the lifting seat (801), and the linkage column (802) is fixed on one side of the lifting seat (801) and extends to the inner side of the machine body (1);

the two moving seats (803) are slidably mounted inside the machine body main body (1) and located below the lifting seat (801), the two moving seats (803) are symmetrically distributed by taking the lifting seat (801) as a center, one ends, far away from each other, of the two moving seats (803) are provided with first expansion springs (808), one sides of the moving seats (803) are rotatably connected with processing rollers (804) penetrating through the inner side of the machine body main body (1), the outer wall of each processing roller (804) is provided with a guide row wheel (805) sleeved with the outer wall of the cutting steel wire (7), and grooves matched with the outer wall of the cutting steel wire (7) are formed in the guide row wheel (805);

rotate and cup joint and be in the rotating sleeve (806) of linkage post (802), processing roller (804) outer wall, the outer wall of linkage post (802) is rotated and is connected with two rotating sleeve (806), just two on linkage post (802) outer wall rotating sleeve (806) is connected with a gangbar (807) respectively, two the other end of gangbar (807) respectively with two rotating sleeve (806) on processing roller (804) outer wall be connected.

3. The cutter lifting mechanism for quartz wafer cutting machine according to claim 2, wherein said locking unit (9) comprises:

the pressing block (903) is arranged on one side, away from the lifting seat (801), of the linkage column (802), and a connecting column (904) penetrating into the linkage column (802) is arranged on one side, close to the linkage column (802), of the pressing block (903);

a locking gear (902) rotatably sleeved on the outer wall of the linkage column (802), wherein the locking gear (902) is positioned between the rotating sleeve (806) and the lifting seat (801), and a locking strip (901) is fixedly connected to one end, positioned on the locking gear (902), of the inner side of the machine body main body (1);

the moving column (905) is arranged inside the linkage column (802) and extends into the lifting seat (801), the moving column (905) is fixedly connected with one side, away from the pressing block (903), of the connecting column (904), and a return spring (906) is arranged at one end, away from the connecting column (904), of the moving column (905);

the telescopic ball (907) is arranged inside the linkage column (802) and extends to the inside of the locking gear (902), the telescopic ball (907) is located on the outer side of the moving column (905), an annular pressing groove (9051) is formed in the position, in which the moving column (905) is in contact with the telescopic ball (907), of the moving column (905), and an annular accommodating groove (9052) is formed in one side, located on the annular pressing groove (9051), of the outer side of the moving column (905).

4. The cutter lifting mechanism for the quartz wafer cutting machine as claimed in claim 2, wherein the inner wall of the machine body (1) is provided with a vertical sliding groove matched with the lifting seat (801), the inner wall of the machine body (1) is provided with a horizontal sliding groove matched with the moving seat (803), the number of the guide row wheels (805) is provided with a plurality of guide row wheels (805), and the plurality of guide row wheels (805) are uniformly distributed on the outer wall of the processing roller (804).

5. The cutter lifting mechanism for the quartz wafer cutting machine according to claim 3, wherein a plurality of telescopic balls (907) are provided, the telescopic balls (907) are annularly distributed around the moving column (905), positioning holes matched with the telescopic balls (907) are formed in the inner side of the locking gear (902), and the number of the positioning holes is matched with that of the telescopic balls (907).

6. The cutter lifting mechanism for the quartz wafer cutting machine as claimed in claim 3, wherein a rack engaged with the locking gear (902) is provided on a side of the locking bar (901) close to the locking gear (902).

7. The cutter lifting mechanism for the quartz wafer cutting machine as claimed in claim 3, wherein the depth of the inner wall of the annular receiving groove (9052) is greater than the depth of the inner wall of the annular pressing groove (9051), and the width of the inner wall of the annular pressing groove (9051) is greater than the diameter of the outer wall of the telescopic ball (907).