CN111116055A

CN111116055A - Water drill processing method

Info

Publication number: CN111116055A
Application number: CN201911041224.6A
Authority: CN
Inventors: 林有艺
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-10-30
Filing date: 2019-10-30
Publication date: 2020-05-08

Abstract

The invention discloses a rhinestone processing method, which comprises the following steps: adopting crystalline glass material containing lead more than 25% as raw material; forming a blank: carrying out blank forming on the raw material by using a blank forming machine; polishing: polishing the formed product by using a polishing wheel; cleaning: cleaning the polished product; checking; chemical plating; the method is simple to implement, and can ensure that the rhinestone is uniformly coated, thereby avoiding the generation of inferior products.

Description

Water drill processing method

Technical Field

The invention belongs to the field of water drill processing, and particularly relates to a water drill processing method.

Background

The crystal glass is the main component of the crystal diamond, and is an accessory of the ornament obtained by cutting artificial crystal glass into diamond facets, and the material is more economical, and has the visual effect of diamond-like dazzling feeling. Therefore, the rhinestone is popular with people, but in the existing rhinestone processing method, in the step of coating, as the rhinestones are stacked together when being placed in a vacuum coating machine, the situation that the whole surfaces of the rhinestones to be coated face upwards cannot be guaranteed, and therefore, the coating of the rhinestones is not uniform, and defective products are generated.

Disclosure of Invention

The invention provides a water drill processing method which can enable the upper surface and the lower surface of a water drill to be coated so as to enable the water drill to be coated uniformly.

In order to achieve the purpose, the invention adopts the following technical scheme: a method for processing a rhinestone comprises the following steps:

a water drill processing method is characterized by comprising the following steps:

a. preparing raw materials: adopting crystalline glass material containing lead more than 25% as raw material;

b. forming a blank: carrying out blank forming on the raw material by using a blank forming machine;

c. polishing: polishing the formed product by using a polishing wheel;

d. cleaning: cleaning the polished product;

e. and (4) checking: placing the cleaned product under a lamp to inspect a finished product;

f. chemical plating: e, plating silver on the bottom of the product after the step e;

g. coating; and f, coating the product after the step f by using vacuum coating equipment.

The vacuum coating equipment in the step g comprises a base, a base space arranged in the base, a vacuum pump fixedly arranged on the upper surface of the base, a feeding chute arranged on the upper end wall of the base space, a feeding door hinged on the rear side of the feeding chute, a handle fixedly arranged on the upper surface of the feeding door, a vent hole fixedly arranged on the front end wall of the base space, an evaporator arranged on the front side of the base, a vent pipe communicated between the evaporator and the vent hole, a discharge hole arranged on the right end wall of the base space, a discharge door hinged on one side of the discharge hole, a handle arranged on the right end surface of the discharge door, a feeding device arranged in the base space and a turn-over device arranged on the feeding device; the feeding device comprises a feeding shell fixedly arranged on the rear end wall of the base space, a feeding space arranged in the feeding shell and communicated up and down, a gear shell fixedly arranged on the rear end surface of the base and a discharging shell;

the step of utilizing the vacuum coating machine to carry out the coating film to the water bores is as follows, open the feed gate with the hand, pour the water bores into in the feeding casing, the feed gate is closed, the vacuum pump is opened, take out into vacuum in the frame space, the evaporimeter starts, evaporate the metal of coating film to the gaseous state, then let in the frame space, material feeding unit starts, pave the water bores and utilize the gaseous metal to carry out the coating film to the one side that the water bores up, turn-over device starts, with the other side up of water bores, carry out the coating film with the another side of water bores, pour the water bores after the coating film is accomplished into ejection of compact casing.

The cleaning operation is to put the rhinestone into water, and the ultrasonic oscillator is utilized to generate fluctuation of water flow so as to clean the rhinestone.

And the polishing step is to place the formed rhinestone blank on a workbench and polish the rhinestone by using a polishing wheel.

The inspection is performed by putting the washed article under a lamp and inspecting whether the article is acceptable by observing the degree of reflection thereof.

The turnover device comprises a fifth vertical plate fixedly arranged on the right end wall of the machine base space, a circular ring plate fixedly arranged on the rear end face of the fifth vertical plate, and a plurality of clamping assemblies respectively rotatably arranged on the grooves, wherein the front end of the fifth transmission shaft is rotatably connected with the rear end face of the fifth vertical plate.

The step of utilizing the turn-over device to carry out the turn-over to the water brill is as follows, and the rotary drum is rotatory, and when the push rod leaned on with the ring plate, clamping component pressed from both sides the water brill tightly, when the water brill after rotary drum will press from both sides tightly was rotatory to the right side from the left side, clamping component loosened.

The clamping assembly comprises a push groove rotatably arranged on the end wall of the groove, a rotating shaft rotatably arranged on the rear end wall of the push groove, a push block movably arranged in the push groove, two tension springs respectively fixedly arranged between the top of the push groove and the push block, a rotating plate fixedly arranged at the rear end of the rotating shaft, a push rod arranged at the front end of the rotating shaft and matched with the circular plate, a matching groove arranged on the end face of one end of the push rod, a connecting shaft rotatably arranged in the matching groove and a rolling wheel fixedly arranged on the outer surface of the connecting shaft;

the step of utilizing clamping assembly to press from both sides tight brill is as follows, through the contact of ring board with the push rod, the push rod moves down, drives the rotor plate and moves down, and the rotor plate drives the piece that pushes away and moves down to can clip the brill that lies in the recess.

In conclusion, the method has the advantages that the method is simple to implement, and the rhinestone can be uniformly coated, so that inferior products are avoided.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a first top view of the present invention;

FIG. 3 is a second top view of the present invention;

FIG. 4 is a cross-sectional view taken at A-A of FIG. 2;

FIG. 5 is a cross-sectional view taken at D-D of FIG. 3;

FIG. 6 is a cross-sectional view taken at F-F of FIG. 2;

FIG. 7 is a cross-sectional view taken at E-E of FIG. 2;

FIG. 8 is an enlarged view of a portion of FIG. 7 at G;

fig. 9 is a schematic structural diagram of a rhinestone.

Detailed Description

c. polishing: polishing the formed product by using a polishing wheel;

d. cleaning: cleaning the polished product;

g. film coating: and f, coating the product after the step f by using vacuum coating equipment.

As shown in fig. 1-8, the vacuum coating apparatus in step g includes a base 1, a base space disposed in the base 1, a vacuum pump 2 fixedly disposed on the upper surface of the base 1, a feeding chute disposed on the upper end wall of the base space, a feeding gate 3 hinged on the rear side of the feeding chute, a handle fixedly disposed on the upper surface of the feeding gate 3, a vent fixedly disposed on the front end wall of the base space, an evaporator 5 disposed on the front side of the base 1, a vent pipe 6 communicated between the evaporator 5 and the vent hole, a discharge hole disposed on the right end wall of the base space, a discharge gate 7 hinged on one side of the discharge hole, a handle disposed on the right end surface of the discharge gate 7, a feeding device disposed in the base space, and a turn-over device disposed on the feeding device.

The feeding device comprises a feeding shell 8 fixedly arranged on the rear end wall of the base space, a feeding space which is arranged in the feeding shell and is communicated up and down, a gear shell 30 fixedly arranged on the rear end surface of the base 1, a gear space arranged in the gear shell 30, a first transmission shaft 31 rotatably arranged on the rear end wall of the gear space, a second transmission shaft 32 rotatably arranged between the front end wall and the rear end wall of the feeding shell 8, a first transmission belt 9 in transmission connection between the first transmission shaft 31 and the second transmission shaft 32, a first gear 33 fixedly arranged on the outer surface of the first transmission shaft 31, a first belt pulley 34 fixedly arranged on the rear side of the first gear 33, a first supporting plate 10 fixedly arranged on the right side of the first transmission belt 9, a first vertical plate 11 fixedly arranged on the left end wall of the base space, a second vertical plate 12 fixedly arranged at the lower end of the first vertical plate 11, a second supporting plate 13 fixedly arranged between the first vertical plate 11 and the rear end wall of the base space, A third transmission shaft 35 rotatably arranged at the rear end wall of the gear space, a fourth transmission shaft 36 rotatably arranged between the rear end wall of the gear space and the first vertical plate 11, a second transmission belt 15 in transmission connection between the third transmission shaft 35 and the fourth transmission shaft 36, a second belt wheel 136 fixedly arranged on the outer surface of the third transmission shaft 35, a first belt 37 in transmission connection between the first belt wheel 34 and the second belt wheel 136, a third belt wheel 99 fixedly arranged on the outer surface of the third transmission shaft 35, a third supporting plate 16 fixedly arranged on the right side of the second transmission belt 15, a driving member fixedly arranged on the rear end surface of the gear housing 30, a first intermittent gear 39 fixedly arranged at the output end of the driving member, a second intermittent gear 40 fixedly arranged on the rear side of the first intermittent gear 39, a fourth transmission shaft 41 rotatably arranged at the rear end wall of the gear space, a second gear 42 fixedly arranged on the outer surface of the fourth transmission shaft 41 and meshed with the first intermittent gear 39, a second intermittent gear 40 fixedly arranged on the, A transmission hole arranged at the rear end wall of the base space, a fifth transmission shaft 43 rotatably arranged in the transmission hole, a third gear 44 fixedly arranged at the front end of the fifth transmission shaft 43 and meshed with the second intermittent gear 40, a brake fixedly arranged on the fifth transmission shaft 43, a rotary drum 17 fixedly arranged at the front end of the fifth transmission shaft 43, eight grooves fixedly distributed on the outer surface of the rotary drum 17 in the circumferential direction, a sixth transmission shaft 45 rotatably arranged at the rear end wall of the gear space, a fourth belt pulley 46 fixedly arranged on the outer surface of the sixth transmission shaft 45, a second belt 47 in transmission connection between the fourth belt pulley 46 and the third belt pulley 99, a third vertical plate 48 fixedly arranged at the right end wall of the base space, a fourth vertical plate 49 fixedly arranged at the front end surface of the third vertical plate 48, and a seventh rotating shaft rotatably arranged between the rear end wall of the base space and the rear end surface of the fourth vertical plate 49, A third conveyor belt 50 connected between the seventh transmission shaft and the sixth transmission shaft 45 in a transmission manner, a discharge shell 51 arranged on the lower side of the third conveyor belt 50, and an electric control door fixedly arranged on the left end wall of the feeding space and between the first conveyor belt, wherein the step of paving and coating the rhinestones by using a feeding device is as follows; the feeding door is opened by hand, the rhinestone is poured into the feeding space, the driving piece is started, the driving piece drives the first intermittent gear 39 to rotate clockwise, the first intermittent gear 39 drives the second gear 42 to rotate, the second gear 42 drives the first gear 33 to rotate, the first gear 33 drives the first conveyor belt to move leftwards, the first gear 33 drives the first belt pulley 136 to rotate, the first belt pulley 136 drives the second conveyor belt 15 to move rightwards, the first belt pulley 136 drives the second belt pulley 35 to rotate, the second belt pulley 35 drives the third belt pulley 99 to rotate, the third belt pulley 99 drives the fourth belt pulley 46 to rotate, the fourth belt pulley 46 drives the third conveyor belt 50 to move rightwards, the electric control door is opened, when the first intermittent gear is separated from the second gear, the second intermittent gear is meshed with the third gear, and the third gear drives the rotating barrel to rotate; the distance between the left end wall of the feeding space and the first conveyor belt is set to be slightly larger than the volume of one rhinestone but smaller than twice the volume of one rhinestone, so that only one row of rhinestones can be accommodated at a time, the rhinestones can fall onto the second conveyor belt from the first conveyor belt in a row, and each rhinestone can be flatly laid on the second conveyor belt under the condition that the second conveyor belt continuously moves rightwards, and the flatly laid rhinestones are conveyed into the grooves of the rotary cylinder, so that the situation that the rhinestones are stacked together and cannot be uniformly coated to generate defective products is avoided, and the upper surfaces of the rhinestones can be uniformly coated; the teeth are arranged at the seventh eighth part of the outer surface of the first intermittent gear, and the teeth are arranged at the eighth part of the outer surface of the second intermittent gear, so that when the first intermittent gear cannot drive the first conveyor belt and the second conveyor belt to move, the rotary drum rotates, when the grooves in the rotary drum are fully paved with the rhinestones, the rotary drum rotates for forty-five degrees, the next empty groove can rotate to understand the right side of the second conveyor belt, and therefore the situation that the rhinestones move leftwards after touching the outer surface of the rotary drum when the rhinestones are continuously conveyed by the second conveyor belt during rotation of the rotary drum to cause local accumulation of the rhinestones is avoided, uneven film coating caused by local accumulation of the rhinestones is avoided, and the stability of equipment is improved; the two side walls of the groove are inclined surfaces, so that the rhinestone can move towards the groove through the inclined surfaces, and the groove can be fully paved; the distance between the upper side wall and the lower side wall of the groove is set to be slightly larger than the volume of one rhinestone but smaller than the two times of the volume of the one rhinestone, so that the rhinestones can be prevented from being accumulated together in the groove, and the stability of the equipment is improved.

The turn-over device comprises a fifth vertical plate 52 fixedly arranged on the right end wall of the machine base space, a circular ring plate 53 fixedly arranged on the rear end face of the fifth vertical plate 52, and eight clamping assemblies respectively rotatably arranged on the eight grooves, wherein the front end of the fifth transmission shaft 43 is rotatably connected with the rear end face of the fifth vertical plate 52.

The clamping assembly comprises a pushing groove rotatably arranged on the end wall of the groove, a rotating shaft 54 rotatably arranged on the rear end wall of the pushing groove, a pushing block 55 movably arranged in the pushing groove, two tension springs 56 respectively fixedly arranged between the top of the pushing groove and the pushing block 55, a rotating plate 57 fixedly arranged at the rear end of the rotating shaft 54, a push rod 58 arranged at the front end of the rotating shaft 54 and matched with the annular plate 53, a matching groove arranged at one end face of the push rod 58, a connecting shaft rotatably arranged in the matching groove, and a rolling wheel 61 fixedly arranged on the outer surface of the connecting shaft; the rotary drum rotates, when the push rod 58 abuts against the annular plate 53, the push rod 58 moves downwards to drive the rotary plate 57 to move downwards, the rotary plate 57 drives the pushing block 55 to move downwards, so that the rhinestones in the grooves can be clamped, the rhinestones in the rotary drum can be always in a clamped state before rotating to the right side, the situation that the rhinestones in the grooves are staggered and stacked together due to the fact that gravity downwards when the grooves rotate to the uppermost side is avoided, and therefore stability of equipment is improved; when the rhinestones are rotated to be close to the upper surface of the third conveyor belt, the push rods 58 are just separated from the circular ring plate 53, so that the push block 55 is loosened under the action of the tension spring, and the rhinestones fall onto the third conveyor belt from the grooves; the rhinestone falls when rotating to a distance which is stronger than the distance between the rhinestone and the third conveying belt, so that the falling impact force of the rhinestone can be reduced, the rhinestone is prevented from bouncing up and turning over again after falling on the third conveying belt due to overlarge impact force of the rhinestone, and the other side of the rhinestone which is not coated with a film can be coated by rotating the rhinestone from the left side to the right side through the rotating cylinder; the rhinestones paved on the grooves can be clamped through the arrangement of the clamping assembly, so that the rhinestones cannot deviate or misplace in the rotating process, and the upward surface of the rhinestones falling on the third conveying belt can be ensured to be the surface which is not coated with a film; the water drill can be clamped tightly by the clamping device without a driving piece through the arrangement of the circular ring plate, so that the driving piece is saved, and the energy is saved.

The driving member is not only a moving motor, but also a driving device for driving the first intermittent gear to rotate, and also a manual driving.

The evaporator, the vacuum pump, the band brake and the electric control door are all in the prior art, and therefore the description is omitted.

The last fixed position inductor that is provided with of first intermittent gear, position inductor start to embrace when first intermittent gear is rotatory 315 degrees and brake, embrace when first intermittent gear is rotatory 45 degrees once more and brake and close to can make the fourth gear can not take place rotatoryly because of the gravity of water brill when the recess of a rotatory section of thick bamboo is put into to water brill when not having gear rather than meshing, thereby make equipment more stable.

The working principle is as follows: the step of utilizing the vacuum coating machine to carry out the coating film to the water bores is as follows, open feed gate 3 with the hand, pour the water bores into in the feed casing, feed gate 3 closes, vacuum pump 2 opens, take out into vacuum in the frame space, the evaporimeter starts, evaporate the metal evaporation of coating film for the gaseous state, then let in the frame space, material feeding unit starts, pave the water bores and utilize gaseous metal to carry out the coating film to the one side that the water bores faced up, turn-over device starts, face up the other side of water bores, carry out the coating film with the another side of water bores, pour the water bores after the coating film is accomplished into in the ejection of compact casing, open the discharge door, can take out ejection of compact casing from equipment.

Claims

1. A water drill processing method is characterized by comprising the following steps:

c. polishing: polishing the formed product by using a polishing wheel;

d. cleaning: cleaning the polished product;

g. film coating: f, coating the product after the step f by using vacuum coating equipment;

the vacuum coating equipment in the step g comprises a base (1), a base space arranged in the base (1), a vacuum pump (2) fixedly arranged on the upper surface of the base (1), a feeding groove arranged on the upper end wall of the base space, a feeding door (3) hinged on the rear side of the feeding groove, a handle fixedly arranged on the upper surface of the feeding door (3), an air vent fixedly arranged on the front end wall of the base space, an evaporator (5) arranged on the front side of the base (1), a vent pipe (6) communicated and arranged between the evaporator (5) and the air vent, a discharge hole arranged on the right end wall of the base space, a discharge door (7) hinged on one side of the discharge hole, a handle arranged on the right end surface of the discharge door (7), a feeding device arranged in the base space and a turn-over device arranged on the feeding device; the feeding device comprises a feeding shell (8) fixedly arranged on the rear end wall of the base space, a feeding space which is arranged in the feeding shell and is communicated up and down, a gear shell (30) fixedly arranged on the rear end surface of the base (1) and a discharging shell (51);

the step of utilizing the vacuum coating machine to carry out the coating film to the water bores is as follows, open feed door (3) with the hand, pour the water bores into in the feeding casing, feed door (3) are closed, vacuum pump (2) are opened, take out into the vacuum in the frame space, the evaporimeter starts, evaporate the metal of coating film into the gaseous state, then let in the frame space, material feeding unit starts, level the water bores and utilize gaseous metal to carry out the coating film to the one side that the water bores faced up, turn-over device starts, with the other side of water bores up, carry out the coating film with the another side of water bores, pour the water bores after the coating film is accomplished into in the ejection of compact casing.

2. A rhinestone machining method according to claim 2, characterized in that: the cleaning operation is to put the rhinestone into water, and the ultrasonic oscillator is utilized to generate fluctuation of water flow so as to clean the rhinestone.

3. A rhinestone machining method according to claim 3, characterized in that: and the polishing step is to place the formed rhinestone blank on a workbench and polish the rhinestone by using a polishing wheel.

4. The rhinestone machining method according to claim 4, characterized in that: the inspection is performed by putting the washed article under a lamp and inspecting whether the article is acceptable by observing the degree of reflection thereof.

5. A method of processing a rhinestone according to claim 1, characterized in that: the turnover device comprises a fifth vertical plate (52) fixedly arranged on the right end wall of the space of the base, a circular plate (53) fixedly arranged on the rear end face of the fifth vertical plate (52), and a plurality of clamping assemblies respectively rotatably arranged on the grooves, wherein the front end of the fifth transmission shaft (43) is rotatably connected with the rear end face of the fifth vertical plate (52);

the step of turning the rhinestone by using the turning device is as follows, the rotary drum (17) rotates, when the push rod (58) abuts against the circular ring plate (53), the clamping assembly clamps the rhinestone, and when the rotary drum (17) rotates the clamped rhinestone from the left side to the right side, the clamping assembly is loosened.

6. The rhinestone machining method according to claim 5, characterized in that: the clamping assembly comprises a pushing groove rotatably arranged on the end wall of the groove, a rotating shaft (54) rotatably arranged on the rear end wall of the pushing groove, a pushing block (55) movably arranged in the pushing groove, two tension springs (56) fixedly arranged between the top of the pushing groove and the pushing block (55) respectively, a rotating plate (57) fixedly arranged at the rear end of the rotating shaft (54), a push rod (58) arranged at the front end of the rotating shaft (54) and matched with the circular ring plate (53), a matching groove arranged on the end face of one end of the push rod (58), a connecting shaft rotatably arranged in the matching groove, and a rolling wheel (61) fixedly arranged on the outer surface of the connecting shaft;

the step of clamping the rhinestone by using the clamping assembly is as follows, the push rod (58) moves downwards by the contact of the annular plate (53) and the push rod (58), the rotating plate (57) is driven to move downwards, and the rotating plate (57) drives the positioning block (55) to move downwards, so that the rhinestone positioned in the groove can be clamped.