CN112158574A

CN112158574A - Two-sided tipping arrangement is used in processing of single double-sided circuit board

Info

Publication number: CN112158574A
Application number: CN202011265405.XA
Authority: CN
Inventors: 赖致升; 赖学良
Original assignee: Shenzhen Junxin Aluminum Plate Ltd
Current assignee: Shenzhen Junxin Aluminum Plate Ltd
Priority date: 2020-11-13
Filing date: 2020-11-13
Publication date: 2021-01-01
Anticipated expiration: 2040-11-13
Also published as: CN112158574B

Abstract

The invention relates to a turnover device, in particular to a double-side turnover device for processing a single-sided circuit board and a double-sided circuit board. The technical problem is to provide a double-sided turnover device for processing a single-sided or double-sided circuit board, which can automatically turn over, has good turnover effect and is convenient to operate. The technical scheme of the invention is that the double-sided turnover equipment for processing the single-sided and double-sided circuit boards comprises: a base; the middle part of the base is provided with a turnover component; the lower pressing component is arranged on the upper side of the overturning component. The invention has the beneficial effects that: under the effect of upset subassembly and push down the subassembly, people place the circuit board between the year material piece, then start first cylinder, the telescopic link of first cylinder can drive the connecting rod and reciprocate, under a series of transmissions, can drive ratchet wheel and rotate one hundred eighty degrees, ratchet wheel can drive the rotation axis and carry the rotatory one hundred eighty degrees of material piece to turn over the circuit board, effectual people's work efficiency that has improved.

Description

Two-sided tipping arrangement is used in processing of single double-sided circuit board

Technical Field

The invention relates to a turnover device, in particular to a double-side turnover device for processing a single-sided circuit board and a double-sided circuit board.

Background

The name of the circuit board is ceramic circuit board, alumina ceramic circuit board, aluminum nitride ceramic circuit board, PCB board printed circuit board, etc. The circuit board enables the circuit to be miniaturized and visualized, and plays an important role in batch production of fixed circuits and optimization of electric appliance layout.

When the circuit board punches or at the in-process of clearance surface in processing, in order to make its working effect better, the people can overturn to the another side after its one side processing is accomplished, at the in-process that overturns the circuit board, generally all manual overturn it with it, when manual upset, can cause the circuit board to landing downwards, and speed is slower moreover, has reduced people's work efficiency, if the appetite foot of circuit board is many, also can cause the condition of wasting time and energy.

Therefore, it is particularly necessary to design a double-side turnover device for processing a single-sided or double-sided circuit board, which can automatically turn over, has a good turnover effect and is convenient to operate, so that some troubles and dangers possibly brought by most manual operations are eliminated, and the working efficiency is improved to solve the above disadvantages.

Disclosure of Invention

In order to overcome when manual upset, can cause the circuit board landing downwards, speed is slower moreover, has reduced people's work efficiency, if the appetite foot of circuit board is many, also can cause the shortcoming that wastes time and energy, technical problem: the double-sided turnover equipment for processing the single-sided and double-sided circuit boards is capable of automatically turning over, good in turnover effect and convenient to operate.

The technical implementation scheme of the invention is as follows: the utility model provides a two sides tipping arrangement is used in single two-sided circuit board processing, including: a base; the middle part of the base is provided with a turnover component; the lower pressing component is arranged on the upper side of the overturning component.

Optionally, the flipping component comprises: the two sides of the upper middle part of the base are provided with the first support frames; the guide rods are arranged on two sides of the upper part of the first support frame; the upper parts of the guide rods are both provided with a first sliding block in a sliding manner; the first springs are connected between the first sliding block and the first support frame and are respectively sleeved on the guide rods; the bearings are arranged between the first sliding blocks on the two sides; the rotating shafts are rotatably arranged in the bearings; the inner sides of the rotating shafts are provided with the material loading blocks in a sliding manner; the outer sides of the rotating shafts are provided with ratchet gears; the ratchet bar group is arranged in the middle of the first support frame, and the ratchet bar group on the same side is matched with the ratchet gear.

Optionally, the pressing assembly comprises: the second support frame is arranged between the tops of the first support frames; the first cylinder is arranged on the upper side of the second support frame; the telescopic rod of the first cylinder is provided with a connecting rod; the two sides of the connecting rod are symmetrically provided with pressing rods, and the bottoms of the pressing rods are respectively contacted with the first sliding blocks.

Optionally, still include the chucking subassembly, the chucking subassembly includes: the inner sides of the first sliding blocks are provided with first supporting blocks; the first supporting blocks are provided with clamping rods in a sliding mode, the rotating shafts are symmetrically provided with round holes, and the clamping rods are matched with the round holes respectively; the second springs are connected between the clamping rods and the first supporting blocks and are respectively sleeved on the clamping rods; the outer sides of the clamping rods are provided with first wedge-shaped blocks; the two sides of the middle part of the first support frame are provided with the second support blocks; the inner sides of the first push rod and the second support block are both provided with a first push rod in a sliding manner, and the first push rods are respectively matched with the first wedge-shaped blocks; and a third spring is connected between the first push rod and the second supporting block and is respectively sleeved on the first push rod.

Optionally, the device further comprises a clamping assembly, wherein the clamping assembly comprises: the inner sides of the upper parts of the first support frames are provided with first ejector blocks; the fixed blocks are arranged on the outer sides of the material carrying blocks, and the fixed blocks are matched with the first jacking blocks; and the fourth springs are connected between the material loading block and the rotating shaft.

Optionally, the device further comprises a separation assembly, wherein the separation assembly comprises: the periphery of the base is provided with the groove blocks; the inner sides of the groove blocks are both provided with a second sliding block in a sliding way; two fifth springs are connected between the second sliding block and the groove block; the top of the second sliding block is provided with a first supporting rod; the upper parts of the first supporting rods are provided with groove rods, and the groove rods on the two sides are matched with each other; the middle part of the inner side of the first supporting rod is provided with a second wedge-shaped block; the third sliding blocks are arranged on two sides of the middle part of the first support frame in a sliding manner; the second push rods are arranged on the outer sides of the third slide blocks, and two sides of the bottom of each third slide block are respectively matched with the second wedge-shaped blocks; the pressing block is arranged between the tops of the second push rods and matched with the bearing; and the sixth springs are connected between the third sliding block and the first support frame and are respectively sleeved on the first support frame.

Optionally, still include the pay-off subassembly, the pay-off subassembly includes: a second supporting rod is arranged between the bottoms of the groove rods on one side; the second cylinder is arranged on the second supporting rod; the telescopic rod of the second cylinder is provided with a second ejector block; and the feeding frame is arranged between the tops of the first supporting rods on one side.

Optionally, the sixth spring is a compression spring.

The invention has the beneficial effects that:

1. under the effect of upset subassembly and push down the subassembly, people place the circuit board between the year material piece, then start first cylinder, the telescopic link of first cylinder can drive the connecting rod and reciprocate, under a series of transmissions, can drive ratchet wheel and rotate one hundred eighty degrees, ratchet wheel can drive the rotation axis and carry the rotatory one hundred eighty degrees of material piece to turn over the circuit board, effectual people's work efficiency that has improved.

2. Under the effect of chucking subassembly, the rotation epaxial round hole can be blocked to the kelly for the rotation axis can not be because the effect of external force is rotatory, makes the effect of upset out better, has improved work efficiency.

3. Under clamping assembly's effect, when carrying the material piece and moving down, can drive the fixed block and move down, when the fixed block breaks away from with first kicking block, can drive the fixed block and carry the inboard removal of material piece, thereby carry the material piece and press from both sides the circuit board tightly for can not break away from with carrying the material piece during the upset, the effectual circuit board of having protected can not the landing to ground.

4. Under the effect of pay-off subassembly, people can place a plurality of circuit boards in the pan feeding frame, start the second cylinder, and the telescopic link of second cylinder can drive the second kicking block back-and-forth movement, and when the second kicking block moved forward, can promote the circuit board of downside to carrying on the material piece, and is so repeated for its automatic unloading work that carries on.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of another perspective structure according to the present invention.

Fig. 3 is a first partial structure diagram and a cross-sectional view of the present invention.

FIG. 4 is a second partial structure diagram of the present invention.

Fig. 5 is a third partial structural schematic view and a sectional view of the present invention.

Fig. 6 is a fourth partial structural schematic view and a sectional view of the present invention.

Fig. 7 is a schematic structural view and a sectional view of a fifth part of the present invention.

FIG. 8 is a schematic diagram of a sixth partial structure according to the present invention.

In the above drawings: 1: base, 2: flip assembly, 201: first support bracket, 202: first slider, 203: guide bar, 204: first spring, 205: bearing, 206: rotation axis, 207: a loading block, 208: ratchet gear, 209: ratchet bar group, 3: push-down assembly, 301: second support, 302: first cylinder, 303: connecting rod, 304: pressure lever, 4: chucking assembly, 401: first support block, 402: jamming rod, 403: second spring, 404: first wedge block, 405: second support block, 406: first push rod, 407: third spring, 5: clamping assembly, 501: first top block, 502: fixed block, 503: fourth spring, 6: separation assembly, 601: groove block, 602: second slider, 603: fifth spring, 604: first support bar, 605: grooved bar, 606: second wedge block, 607: a briquette, 608: third slider, 609: second push rod, 610: sixth spring, 7: a feeding assembly, 701: second support bar, 702: second cylinder, 703: second top block, 704: and (4) feeding the material frame.

Detailed Description

The following description is only a preferred embodiment of the present invention, and does not limit the scope of the present invention.

Example 1

The utility model provides a two sides tipping arrangement is used in single double-sided circuit board processing, as shown in figure 1, figure 2, figure 3 and figure 4, including base 1, upset subassembly 2 and push down subassembly 3, the middle part is equipped with upset subassembly 2 on the base 1, and 2 upsides of upset subassembly are equipped with and push down subassembly 3.

The turnover component 2 comprises a first support frame 201, a first sliding block 202, a guide rod 203, a first spring 204, a bearing 205, a rotating shaft 206, a material loading block 207, a ratchet gear 208 and a ratchet bar group 209, wherein the first support frame 201 is arranged on the left side and the right side of the upper middle part of the base 1, the guide rods 203 are arranged on the front side and the rear side of the upper part of the first support frame 201, the first sliding block 202 is arranged on the upper part of the guide rod 203 in a sliding manner, the first spring 204 is connected between the first sliding block 202 and the first support frame 201, the first spring 204 is respectively sleeved on the guide rod 203, the bearing 205 is arranged between the first sliding blocks 202 on the front side and the rear side, the rotating shaft 206 is rotatably arranged in the bearing 205, the material loading block 207 is arranged on the inner side of the rotating shaft 206 in a sliding manner, the ratchet gear 208 is arranged on the outer side of the rotating shaft 206.

The pressing component 3 comprises a second supporting frame 301, a first air cylinder 302, a connecting rod 303 and a pressing rod 304, the second supporting frame 301 is arranged between the tops of the first supporting frames 201, the first air cylinder 302 is arranged on the upper side of the second supporting frame 301, the connecting rod 303 is arranged on the telescopic rod of the first air cylinder 302, the pressing rods 304 are symmetrically arranged on the left side and the right side of the connecting rod 303, and the bottoms of the pressing rods 304 are respectively contacted with the first sliding blocks 202.

When a circuit board is placed between the material loading blocks 207, and then the first air cylinder 302 is started, the telescopic rod of the first air cylinder 302 drives the connecting rod 303 to move up and down, the connecting rod 303 drives the pressing rod 304 to move up and down, when the pressing rod 304 drives the first sliding block 202 to move down, the first spring 204 is compressed, the first sliding block 202 drives the rotating shaft 206, the material loading block 207 and the ratchet gear 208 to move down, when the ratchet gear 208 is in contact with the ratchet bar group 209, the ratchet gear 208 is driven to rotate one hundred eighty degrees, the ratchet gear 208 drives the rotating shaft 206 and the material loading block 207 to rotate one hundred eighty degrees, so that the circuit board is turned over, when the pressing rod 304 moves up, the pressing rod can be separated from the first sliding block 202, due to the resetting effect of the first spring 204, the rotating shaft 206, the material loading block 207 and the ratchet gear 208 can be driven to move up, when the ratchet gear 208 is in contact with the ratchet bar group 209 again, under the effect of, the ratchet gear 208 can not be driven to rotate, and the working efficiency of people is effectively improved.

Example 2

On the basis of embodiment 1, as shown in fig. 5, 6, 7 and 8, the locking device further includes a locking assembly 4, the locking assembly 4 includes a first supporting block 401, a locking rod 402, a second spring 403, a first wedge-shaped block 404, a second supporting block 405, a first push rod 406 and a third spring 407, the first supporting block 401 is disposed inside the first sliding block 202, the locking rod 402 is slidably disposed on the first supporting block 401, circular holes are symmetrically formed on the rotating shaft 206, the locking rod 402 is respectively engaged with the circular holes, the second spring 403 is connected between the locking rod 402 and the first supporting block 401, the second spring is respectively sleeved on the locking rod 402, the first wedge-shaped block 404 is disposed outside the locking rod 402, the second supporting block 405 is disposed on the front and rear sides of the middle portion of the first supporting block 201, the first push rod 406 is slidably disposed inside the second supporting block 405, the first push rod 406 is respectively engaged with the first wedge-shaped block 404, a third spring 407 is connected between the first push rod 406 and the second supporting block 405, and the third spring 407 is respectively sleeved on the first push rod 406.

In an initial state, the clamping rod 402 will clamp the circular hole on the rotating shaft 206, so that the rotating shaft 206 will not rotate due to the action of external force, when the first sliding block 202 moves downward, the clamping rod 402 and the first wedge-shaped block 404 will be driven to move downward, when the first wedge-shaped block 404 contacts with the first push rod 406, the first wedge-shaped block 404 will drive the clamping rod 402 to move outward, the second spring 403 will be compressed, at this time, the clamping rod 402 will not clamp the rotating shaft 206, when the rotating shaft 206 rotates by one hundred eighty degrees, the first wedge-shaped block 404 will be separated from the first push rod 406, due to the restoring action of the second spring, the first wedge-shaped block 404 and the clamping rod 402 will be driven to move inward, the clamping rod 402 will continue to clamp the circular hole 403 on the rotating shaft 206, when the first sliding block 202 moves upward, the clamping rod 402 and the first wedge-shaped block 404 will be driven to move upward, when the first wedge-shaped block 404 again contacts with the first push rod 406, the first push rod 406 is driven to move outward, the third spring 407 is compressed, and when the first wedge block 404 continues to move upward and is separated from the first push rod 406, the first push rod 406 is driven to move inward to reset due to the reset function of the third spring 407.

The clamping device is characterized by further comprising a clamping assembly 5, wherein the clamping assembly 5 comprises a first ejector block 501, a fixed block 502 and a fourth spring 503, the first ejector block 501 is arranged on the inner side of the upper portion of the first support frame 201, the fixed block 502 is arranged on the outer side of the loading block 207, the fixed block 502 and the first ejector block 501 are matched with each other, and the fourth spring 503 is connected between the loading block 207 and the rotating shaft 206.

In the initial state, the first ejector block 501 is in contact with the fixed block 502, the fourth spring 503 is in a compressed state, when the material loading block 207 moves downwards, the fixed block 502 can be driven to move downwards, when the fixed block 502 is separated from the first ejector block 501, the fixed block 502 and the material loading block 207 can be driven to move inwards due to the reset effect of the fourth spring 503, the material loading block 207 can clamp the circuit board, the circuit board can not be separated from the material loading block 207 during overturning, when the material loading block 207 moves upwards, the fixed block 502 can be driven to move upwards, when the fixed block 502 is in contact with the first ejector block 501, the fixed block 502 and the material loading block 207 can be driven to move outwards, the fourth spring 503 is compressed again, and the circuit board 503 is loosened.

The separating component 6 is further included, the separating component 6 includes a groove block 601, a second sliding block 602, a fifth spring 603, a first supporting rod 604, a groove rod 605, a second wedge block 606, a pressing block 607, a third sliding block 608, a second push rod 609 and a sixth spring 610, the groove block 601 is arranged on the periphery of the base 1, the second sliding block 602 is arranged on the inner side of the groove block 601 in a sliding manner, two fifth springs 603 are connected between the second sliding block 602 and the groove block 601, the first supporting rod 604 is arranged on the top of the second sliding block 602, the groove rod 605 is arranged on the upper portion of the first supporting rod 604, the groove rods 605 on the left side and the right side are matched with each other, the second wedge block 606 is arranged on the middle portion of the first supporting rod 604 in a sliding manner, the third sliding blocks 608 are arranged on the front side and the back side of the middle portion of the first supporting frame 201 in a sliding manner, the second push rod 609 is arranged on the outer side of the third sliding block 608, the pressing block 607 is arranged between the third sliding blocks 608, sixth springs 610 are connected between the third sliding blocks 608 and the first support frame 201, and the sixth springs 610 are respectively sleeved on the first support frame 201.

When the bearing 205 moves downward, the pressing block 607 is driven to move downward, the pressing block 607 drives the third sliding block 608 and the second pushing rod 609 to move downward, the sixth spring 610 is compressed, when the second pushing rod 609 contacts with the second wedge-shaped block 606, the second wedge-shaped block 606 is driven to move outward, the second wedge-shaped block 606 drives the first supporting rod 604, the second sliding block 602 and the slot rod 605 to move outward, the fifth spring 603 is compressed, so that the carrier block 207 does not contact the first support rod 604 when it is turned over, and is separated from the pressing block 607 when the bearing 205 is moved upward, due to the reset action of the sixth spring 610, the pressing block 607, the third sliding block 608 and the second push rod 609 are driven to move upwards to reset, when the second push rod 609 is disengaged from the second wedge-shaped block 606, due to the reset action of the fifth spring 603, the second wedge-shaped block 606, the first support rod 604, the second sliding block 602 and the slot rod 605 are driven to move inwards to reset.

The feeding assembly 7 comprises a second supporting rod 701, a second air cylinder 702, a second ejector block 703 and a feeding frame 704, the second supporting rod 701 is arranged between the bottoms of the rear side groove rods 605, the second air cylinder 702 is arranged on the second supporting rod 701, the second ejector block 703 is arranged on the telescopic rod of the second air cylinder 702, and the feeding frame 704 is arranged between the tops of the rear side first supporting rods 604.

People can place a plurality of circuit boards in pan feeding frame 704, then people start second cylinder 702, the telescopic link of second cylinder 702 can drive second kicking block 703 back-and-forth movement, when second kicking block 703 moves forward, can promote the circuit board of downside to on year material piece 207, second kicking block 703 can reset when moving backward, so repeatedly, circuit board on year material piece 207 can be promoted forward by the circuit board in pan feeding frame 704, thereby push to between the front side groove pole 605, make its automatic unloading work that carries out.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.

Claims

1. The utility model provides a two sides tipping arrangement is used in processing of single double-sided circuit board which comprises:

a base (1);

the middle part of the base (1) is provided with a turnover component (2);

the lower pressing component (3) is arranged on the upper side of the overturning component (2).

2. A double-sided inverting apparatus for single and double sided circuit board processing according to claim 1 wherein the inverting assembly (2) comprises:

the two sides of the middle part of the base (1) are provided with a first support frame (201);

the guide rods (203) are arranged on two sides of the upper part of the first support frame (201);

the upper parts of the first sliding blocks (202) and the guide rods (203) are both provided with the first sliding blocks (202) in a sliding manner;

the first springs (204) are connected between the first sliding block (202) and the first supporting frame (201), and the first springs (204) are respectively sleeved on the guide rods (203);

the bearings (205) are arranged between the first sliding blocks (202) on the two sides;

a rotating shaft (206), wherein the rotating shaft (206) is rotatably arranged in the bearing (205);

the inner sides of the rotating shafts (206) are provided with the loading blocks (207) in a sliding manner;

the outer sides of the rotating shafts (206) are provided with ratchet gears (208);

the middle part of the first support frame (201) is provided with the ratchet bar group (209), and the ratchet bar group (209) on the same side is matched with the ratchet wheel (208).

3. A double-sided turnover device for single-and double-sided circuit board processing according to claim 2, characterized in that the hold-down assembly (3) comprises:

the second support frame (301) is arranged between the tops of the first support frames (201);

the first cylinder (302) is arranged on the upper side of the second supporting frame (301);

the connecting rod (303) is arranged on the telescopic rod of the first cylinder (302);

the two sides of the connecting rod (303) are symmetrically provided with the pressing rods (304), and the bottoms of the pressing rods (304) are respectively contacted with the first sliding block (202).

4. A two-sided turning apparatus for single and double sided circuit board processing according to claim 3, further comprising a clamping assembly (4), wherein the clamping assembly (4) comprises:

the inner sides of the first sliding blocks (202) are provided with first supporting blocks (401);

the clamping rods (402) are arranged on the first supporting blocks (401) in a sliding mode, round holes are symmetrically formed in the rotating shaft (206), and the clamping rods (402) are matched with the round holes respectively;

the second springs (403) are connected between the clamping rod (402) and the first supporting block (401), and the second springs (403) are respectively sleeved on the clamping rod (402);

the outer sides of the clamping rods (402) are respectively provided with a first wedge block (404);

the second supporting blocks (405) are arranged on two sides of the middle part of the first supporting frame (201);

the inner sides of the first push rods (406) and the second supporting blocks (405) are respectively provided with a first push rod (406) in a sliding manner, and the first push rods (406) are respectively matched with the first wedge-shaped blocks (404);

and a third spring (407), wherein the third spring (407) is connected between the first push rod (406) and the second supporting block (405), and the third spring (407) is respectively sleeved on the first push rod (406).

5. The double-sided turnover device for processing the single-sided and double-sided circuit boards as claimed in claim 4, further comprising a clamping assembly (5), wherein the clamping assembly (5) comprises:

the inner sides of the upper parts of the first supporting frames (201) are provided with first ejector blocks (501);

the fixing blocks (502) are arranged on the outer sides of the loading blocks (207), and the fixing blocks (502) are matched with the first ejector blocks (501);

and fourth springs (503) are connected between the material loading block (207) and the rotating shaft (206).

6. The double-sided turnover device for processing the single-sided and double-sided circuit boards as claimed in claim 5, further comprising a separating assembly (6), wherein the separating assembly (6) comprises:

the groove blocks (601) are arranged on the periphery of the base (1);

the inner sides of the groove blocks (601) are both provided with a second sliding block (602) in a sliding manner;

two fifth springs (603) are connected between the second sliding block (602) and the groove block (601);

the top of each first supporting rod (604) and the top of each second sliding block (602) are provided with the first supporting rod (604);

the upper parts of the first supporting rods (604) are provided with groove rods (605), and the groove rods (605) on the two sides are matched with each other;

the middle part of the inner side of each first support rod (604) is provided with a second wedge-shaped block (606);

the third sliding blocks (608) are arranged on two sides of the middle part of the first supporting frame (201) in a sliding mode;

the second push rods (609) are arranged on the outer sides of the third sliding blocks (608), and two sides of the bottom of each third sliding block (608) are respectively matched with the second wedge-shaped block (606);

the pressing block (607) is arranged between the tops of the second push rods (609), and the pressing block (607) is matched with the bearing (205);

and a sixth spring (610) is connected between the third sliding block (608) and the first support frame (201), and the sixth spring (610) is respectively sleeved on the first support frame (201).

7. The double-sided turnover device for processing the single-sided and double-sided circuit boards as claimed in claim 6, further comprising a feeding assembly (7), wherein the feeding assembly (7) comprises:

a second support rod (701) is arranged between the bottoms of the groove rods (605) on one side of the second support rod (701);

the second cylinder (702) is arranged on the second support rod (701);

the telescopic rod of the second cylinder (702) is provided with a second ejector block (703);

the material feeding frame (704) is arranged between the tops of the first supporting rods (604) on one side of the material feeding frame (704).

8. The double-sided flip apparatus for processing the single-sided and double-sided circuit boards as claimed in claim 6, wherein the sixth spring (610) is a compression spring.