CN118670336B - Copper-clad plate surface flatness detection equipment - Google Patents

Abstract

The present invention relates to the technical field of flatness detection equipment, and in particular to a surface flatness detection equipment for a copper clad laminate, comprising: a base, a detection mechanism and a detection probe; a mounting block is fixedly connected to the base; a pair of the detection mechanisms are located at the upper and lower sides of the mounting block; the detection probe is installed on the detection mechanism; a pair of the mounting blocks are symmetrically provided with spacing support mechanisms; the present invention arranges a rotating rod and a pressing plate on the mounting block, and the pressing plate clamps the copper clad laminate at intervals on the upper and lower sides of the copper clad laminate, so that the detection probe performs flatness detection at the interval between the pressing plates on the upper and lower surfaces of the copper clad laminate, and after the detection is completed, the pressing plate changes its position, so that the detection probe detects the copper clad laminate again, and the flatness detection of the upper and lower surfaces of the copper clad laminate is completed twice, so that the present invention clamps the upper and lower surfaces while performing flatness detection on the upper and lower surfaces of the drawing at the same time, thereby preventing the copper clad laminate from bending and deforming, thereby affecting the detection effect.

Description

A copper clad laminate surface flatness detection device

Technical Field

The present invention relates to the technical field of flatness detection equipment, and in particular to a copper clad laminate surface flatness detection equipment.

Background Art

Copper clad laminate is a common electronic substrate material used to manufacture printed circuit boards. Copper clad laminate consists of copper foil, PP substrate and developer board. Circuits are etched on the developer board through photochemical reaction, and then the developer board and PP substrate are stacked. Copper foil is then covered on both sides of the stacked board. The board and copper foil are then placed in a hot press for hot pressing, so that the PP substrate, developer board and copper foil on the surface are bonded to form a copper clad laminate.

After hot pressing, the copper clad laminate needs to be tested for copper thickness and flatness. When testing the flatness, the copper clad laminate is placed on the flatness testing equipment, which lifts the copper clad laminate. The testing probe of the flatness testing equipment contacts the copper foil on the upper and lower surfaces of the copper clad laminate to perform the flatness test.

The copper clad laminate is made of elastic PP substrate and copper foil and other materials, so the copper clad laminate is elastic. When the thickness of the copper clad laminate is thin, lifting the copper clad laminate will cause it to bend and deform under the action of gravity, affecting the results of flatness detection and causing limitations.

To this end, we propose a copper clad laminate surface flatness detection device.

Summary of the invention

In view of the deficiencies in the prior art, the present invention provides a copper clad laminate surface flatness detection device, which overcomes the deficiencies in the prior art and aims to solve the problems in the background technology.

To achieve the above object, the present invention provides the following technical solution: a copper clad laminate surface flatness detection device, comprising: a base, a detection mechanism and a detection probe; a mounting block is fixedly connected to the base; a pair of the detection mechanisms are located at the upper and lower sides of the mounting block; the detection probe is installed on the detection mechanism;

A pair of the mounting blocks are symmetrically provided with spacing support mechanisms; the spacing support mechanisms support the copper clad laminate at intervals on the upper and lower surfaces of the copper clad laminate and are staggered to prevent the copper clad laminate from deforming, so that the detection mechanism can detect the flatness of the copper foil on the upper and lower surfaces of the copper clad laminate.

Preferably, the interval support mechanism includes a rotating block, a rotating rod and a pressure plate; two mounting grooves are symmetrically provided on the mounting block; the rotating block is evenly installed in the mounting groove; the rotating blocks in the two mounting grooves on the mounting block are staggered; the rotating rod is rotatably connected to the rotating block; the pressure plate is rotatably connected to the rotating rod; a synchronous gear is fixedly connected to the rotating rod; a synchronous rack is provided in the mounting groove; the synchronous rack is meshed with the synchronous gear; a pushing electric push rod is fixedly connected in the mounting groove; the pushing electric push rod pushes the synchronous rack to move; and a support rod is fixedly connected to the mounting block.

By arranging a rotating rod and a pressing plate on the mounting block, the pressing plates are arranged at intervals on the upper and lower sides of the copper clad laminate, so that the pressing plates clamp the copper clad laminate at intervals on the upper and lower sides of the copper clad laminate, so that the detection probe performs flatness detection at the interval between the pressing plates on the upper and lower surfaces of the copper clad laminate, and after the detection is completed, the pressing plate changes its position, so that the detection probe detects the copper clad laminate again, and the flatness detection of the upper and lower surfaces of the copper clad laminate is completed twice. Therefore, the present invention clamps the upper and lower surfaces while performing flatness detection on the upper and lower surfaces of the drawing at the same time, thereby preventing the copper clad laminate from bending and deforming, which affects the detection effect.

Preferably, the rotating block is slidably connected in the mounting groove.

Preferably, a synchronization block is slidably connected in the mounting groove; a synchronization groove is provided in the synchronization block; the synchronization rack is slidably connected in the synchronization groove; a reset spring is fixedly connected between the synchronization block and the synchronization rack; an opening is provided on the mounting block; a pull rod is threadedly connected on the synchronization block; one end of the pull rod is rotatably connected to the synchronization rack, and the other end is exposed from the opening.

Preferably, a rotating groove is provided on the rotating block; an adjusting block is rotatably connected in the rotating groove, and a push rod is spirally fitted in the rotating groove; an adjusting groove is provided in the push rod; the adjusting block is slidably connected in the adjusting groove; one end of the push rod away from the adjusting block is arranged in a square shape; a square groove is provided on the adjusting block; and the push rod can be inserted into the square groove.

Preferably, a detection block is fixedly connected to the output end of the pushing electric push rod; a detection groove is opened on the detection block; a detection pressure sensor is fixedly connected in the detection groove, and a connecting block is slidably connected in the detection groove; the connecting block is fixedly connected to the synchronization block, and a detection spring is fixedly connected between the connecting block and the detection pressure sensor.

The electric push rod is pushed to drive the synchronization block through the detection block and the connecting block, and then the synchronization rack is driven to move through the synchronization block. When the pressure plate contacts the copper-clad laminate, the force of pushing the electric push rod causes the detection pressure sensor to detect the pressure change, thereby pushing the electric push rod to stop pushing. Therefore, the present invention can prevent the pressure plate from exerting too much force on the copper-clad laminate and leaving a mark on the surface of the copper-clad laminate by arranging the detection pressure sensor.

Preferably, telescopic plates are slidably connected on both sides of the pressure plate; the same flexible block is fixedly connected to the two telescopic plates; an adjusting rod is rotatably connected to the pressure plate; threads with opposite rotation directions are provided at both ends of the adjusting rod, and the two ends of the adjusting rod cooperate with the threads of the two telescopic plates.

Preferably, a support plate is rotatably connected to the telescopic plate.

Preferably, a torsion spring is fixedly connected between the support plate and the telescopic plate.

Beneficial effects of the present invention:

1. The present invention arranges a rotating rod and a pressing plate on the mounting block so that the pressing plates are arranged at intervals on the upper and lower sides of the copper clad laminate, so that the pressing plates clamp the copper clad laminate at intervals on the upper and lower sides of the copper clad laminate, so that the detection probe performs flatness detection at the interval between the pressing plates on the upper and lower surfaces of the copper clad laminate. After the detection is completed, the pressing plate changes its position, so that the detection probe detects the copper clad laminate again, and the flatness detection of the upper and lower surfaces of the copper clad laminate is completed twice. Therefore, the present invention clamps the upper and lower surfaces while performing flatness detection on the upper and lower surfaces of the drawing at the same time, thereby preventing the copper clad laminate from bending and deforming, which affects the detection effect.

2. The present invention sets a detection block and a connecting block between the push electric push rod and the synchronization block. When the pressure plate contacts the copper-clad laminate, the force of pushing the electric push rod causes the detection pressure sensor to detect the pressure change, thereby pushing the electric push rod to stop pushing. Therefore, the present invention can prevent the pressure plate from exerting too much force on the copper-clad laminate and leaving a mark on the surface of the copper-clad laminate by setting the detection pressure sensor.

BRIEF DESCRIPTION OF THE DRAWINGS

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

FIG2 is an enlarged view of point A in FIG1 ;

FIG3 is an enlarged view of point B in FIG1 ;

FIG4 is a cross-sectional view of the mounting block, the synchronous block, the synchronous rack and the rotating block at the cross-sectional view angle of C-C in FIG1 ;

FIG5 is a cross-sectional view of the pressing plate, the telescopic block and the flexible block at the cross-sectional view angle D-D in FIG1;

FIG6 is a cross-sectional view of the rotating block, the adjusting block and the ejector rod in the present invention;

FIG. 7 is a cross-sectional view of the detection block and the connection block in the present invention.

In the figure: 1. base; 2. detection mechanism; 21. detection probe; 3. mounting block; 41. rotating block; 42. rotating rod; 43. pressure plate; 44. mounting slot; 45. synchronous gear; 46. synchronous rack; 47. push electric push rod; 48. support rod; 5. synchronous block; 51. synchronous slot; 52. reset spring; 53. opening; 54. pull rod; 55. detection block; 56. detection slot; 57. detection pressure sensor; 58. connecting block; 59. detection spring; 6. rotating slot; 61. adjusting block; 62. push rod; 63. adjusting slot; 64. square slot; 65. telescopic plate; 66. flexible block; 67. adjusting rod; 68. support plate; 69. torsion spring.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the present invention to clearly and completely describe the technical solutions in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the present invention.

Embodiment 1: Referring to FIG. 1 of the specification, a copper clad laminate surface flatness detection device comprises: a base 1, a detection mechanism 2 and a detection probe 21; a mounting block 3 is fixedly connected to the base 1; a pair of detection mechanisms 2 are located at the upper and lower sides of the mounting block 3; the detection probe 21 is installed on the detection mechanism 2;

A pair of mounting blocks 3 are symmetrically provided with spacing support mechanisms; the spacing support mechanisms support the copper clad laminate at intervals on the upper and lower surfaces of the copper clad laminate and are staggered to prevent the copper clad laminate from deformation, so that the detection mechanism 2 can detect the flatness of the copper foil on the upper and lower surfaces of the copper clad laminate.

With reference to the accompanying drawings 1, 2, 3 and 4 of the specification, in the present invention, the interval support mechanism includes a rotating block 41, a rotating rod 42 and a pressure plate 43; two mounting grooves 44 are symmetrically provided on the mounting block 3; the rotating blocks 41 are evenly installed in the mounting grooves 44; the rotating blocks 41 in the two mounting grooves 44 on the mounting block 3 are arranged alternately; the rotating rod 42 is rotatably connected to the rotating block 41; the pressure plate 43 is rotatably connected to the rotating rod 42; a synchronous gear 45 is fixedly connected to the rotating rod 42; a synchronous rack 46 is provided in the mounting groove 44; the synchronous rack 46 is meshed with the synchronous gear 45; a pushing electric push rod 47 is fixedly connected in the mounting groove 44; the pushing electric push rod 47 pushes the synchronous rack 46 to move; and a support rod 48 is fixedly connected to the mounting block 3.

In the present invention, the staff places the copper clad laminate on the support rod 48, and then pushes the electric push rod 47 to push the synchronous rack 46, so that the synchronous rack 46 drives the synchronous gear 45 and the rotating rod 42 to rotate synchronously, so that the pressure plate 43 rotates in the direction close to the copper clad laminate, and the pressure plate 43 above the copper clad laminate is pressed on the copper clad laminate, and the pressure plate 43 below the copper clad laminate supports the copper clad laminate, and because the positions of the upper and lower groups of rotating blocks 41 on the mounting block 3 are staggered, after the upper and lower groups of pressure plates 43 rotate and contact the copper clad laminate, they are also in a staggered state. Therefore, after the copper clad laminate is set up, the present invention staggers the copper clad laminate, and then the upper and lower groups of detection mechanisms 2 control the corresponding detection probes 21 to move, so that the upper and lower detection probes 21 move to the upper and lower surfaces of the copper clad laminate. 43 are staggered, so there is a gap between the pressure plates 43 on the upper surface of the copper clad laminate, and there is also a gap between the pressure plates 43 on the lower surface of the copper clad laminate. Therefore, the detection probe 21 first performs flatness detection on the intervals of the copper clad laminate, and moves to the next interval for detection after the interval is completed. This is the first detection. After all the intervals are detected, the electric push rod 47 is pushed to pull back the synchronous rack 46, so that the pressure plate 43 rotates in the opposite direction until the rotating rod 42 rotates 180° with the pressure plate 43, and the pressure plate 43 contacts the copper clad laminate again. At this time, the part where the pressure plate 43 contacts the copper clad laminate is the interval during the first detection. At this time, the interval between the pressure plates 43 is the part covered by the pressure plate 43 during the first detection. Then the detection probe 21 starts the second detection, thereby completing the flatness detection of the upper and lower surfaces of the entire copper clad laminate.

The present invention arranges a rotating rod 42 and a pressing plate 43 on the mounting block 3 so that the pressing plates 43 are arranged at intervals on the upper and lower sides of the copper clad laminate, so that the pressing plates 43 clamp the copper clad laminate at intervals on the upper and lower sides of the copper clad laminate, so that the detection probe 21 performs flatness detection at the interval between the pressing plates 43 on the upper and lower surfaces of the copper clad laminate. After the detection is completed, the pressing plate 43 changes its position, so that the detection probe 21 detects the copper clad laminate again, and the flatness detection of the upper and lower surfaces of the copper clad laminate is completed twice. Therefore, the present invention clamps the upper and lower surfaces while performing flatness detection on the upper and lower surfaces of the drawing at the same time, thereby preventing the copper clad laminate from bending and deforming, which affects the detection effect.

4 and 6 of the specification, in the present invention, the rotating block 41 is slidably connected in the mounting groove 44 .

In the present invention, a synchronization block 5 is slidably connected in the mounting groove 44; a synchronization groove 51 is provided in the synchronization block 5; the synchronization rack 46 is slidably connected in the synchronization groove 51; a reset spring 52 is fixedly connected between the synchronization block 5 and the synchronization rack 46; an opening 53 is provided on the mounting block 3; a pull rod 54 is threadedly connected on the synchronization block 5; one end of the pull rod 54 is rotatably connected to the synchronization rack 46, and the other end exposes the opening 53.

In the present invention, a rotating groove 6 is provided on the rotating block 41; an adjusting block 61 is rotatably connected in the rotating groove 6, and a push rod 62 is spirally fitted in the rotating groove 6; an adjusting groove 63 is provided in the push rod 62; the adjusting block 61 is slidably connected in the adjusting groove 63; the end of the push rod 62 away from the adjusting block 61 is set in a square shape; a square groove 64 is provided on the adjusting block 61; the push rod 62 can be inserted into the square groove 64.

Referring to Figures 2 and 7 of the specification, in the present invention, a detection block 55 is fixedly connected to the output end of the electric push rod 47; a detection groove 56 is opened on the detection block 55; a detection pressure sensor 57 is fixedly connected in the detection groove 56, and a connecting block 58 is slidably connected in the detection groove 56; the connecting block 58 is fixedly connected to the synchronization block 5, and a detection spring 59 is fixedly connected between the connecting block 58 and the detection pressure sensor 57.

In the present invention, the staff rotates the pull rod 54 to move the pull rod 54 upward, and pulls the synchronous rack 46 upward to disengage the synchronous rack 46 from the synchronous gear 45. Then the staff moves the rotating block 41 to adjust the spacing between the rotating blocks 41 to adjust the spacing between the pressure plates 43. At the same time, the rotating block 41 can be slid into the installation groove 44 or the number of rotating blocks 41 in the installation groove 44 can be increased to adjust the number of pressure plates 43. Thus, the present invention can change the number and spacing of the pressure plates 43 to be suitable for copper clad laminates of different sizes. In the present invention, the top rod 62 on the rotating block 41 is inserted into the square groove 64 on the adjusting block 61 in the adjacent rotating block 41, so that the top rod 62 separates the rotating blocks 41. Thus, the present invention changes the spacing between the rotating blocks 41 by rotating the adjusting block 61 on the outermost rotating block 41.

In the present invention, the electric push rod 47 is pushed to drive the synchronization block 5 through the detection block 55 and the connecting block 58, and then the synchronization rack 46 is driven to move through the synchronization block 5. When the pressure plate 43 contacts the copper clad laminate, the force of pushing the electric push rod 47 causes the detection pressure sensor 57 to detect the pressure change, thereby pushing the electric push rod 47 to stop pushing. Therefore, the present invention can prevent the pressure plate 43 from exerting too much force on the copper clad laminate and pressing a mark on the surface of the copper clad laminate by setting the detection pressure sensor 57.

Embodiment 2: Based on Embodiment 1, referring to Figure 5 of the specification, in the present invention, telescopic plates 65 are slidably connected to both sides of the pressure plate 43; the same flexible block 66 is fixedly connected to the two telescopic plates 65; an adjusting rod 67 is rotatably connected to the pressure plate 43; both ends of the adjusting rod 67 are provided with threads with opposite rotation directions, and the two ends of the adjusting rod 67 are threadedly matched with the two telescopic plates 65.

In the present invention, a support plate 68 is rotatably connected to the telescopic plate 65 .

In the present invention, a torsion spring 69 is fixedly connected between the support plate 68 and the telescopic plate 65 .

In the present invention, the flexible block 66 on the pressing plate 43 contacts the copper-clad laminate, which can play a buffering role. At the same time, the adjusting rod 67 is rotated, and the two ends of the adjusting rod 67 are screwed to opposite threads, so that the two telescopic plates 65 move in opposite directions, so that the two telescopic plates 65 move away from each other, stretching the flexible block 66, so that the part of the flexible block 66 in contact with the copper-clad laminate is increased, so that the present invention can change the size of the part in contact with the copper-clad laminate. When the copper foil on the surface of the copper-clad laminate is thin, the contact area between the flexible block 66 and the copper-clad laminate is increased to reduce the pressure on the copper foil on the surface of the copper-clad laminate, thereby reducing the copper foil on the surface of the copper-clad laminate. When the copper foil on the surface of the board is thin, the present invention leaves marks on the copper foil on the surface of the copper clad board; in the present invention, the telescopic plate 65 is rotatably connected to the support plate 68 through the torsion spring 69. Therefore, after the telescopic plate 65 moves outward, the support plate 68 is rotated to a downward vertical state under the action of the torsion spring 69, so that the support plate 68 can support the flexible block 66 on both sides of the pressure plate 43 to reduce the support of the flexible block 66 by the pressure plate 43. When the two sides are not supported, the force on the two sides of the flexible block 66 is different from that in the middle, thereby improving the use effect of the flexible block 66 of the present invention.

The above shows and describes the basic principles, main features and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments, and the above embodiments and descriptions are only for explaining the principles of the present invention. Without departing from the spirit and scope of the present invention, the present invention may have various changes and improvements, which fall within the scope of the present invention to be protected; the scope of the present invention to be protected is defined by the attached claims and their equivalents.

Claims (7)

1. A copper clad laminate surface flatness detection device, characterized in that it comprises: a base (1), a detection mechanism (2) and a detection probe (21); a mounting block (3) is fixedly connected to the base (1); a pair of the detection mechanisms (2) are located at the upper and lower sides of the mounting block (3); the detection probe (21) is mounted on the detection mechanism (2); A pair of the mounting blocks (3) are symmetrically provided with spacing support mechanisms; the spacing support mechanisms support the copper clad laminate at intervals on the upper and lower surfaces of the copper clad laminate and are arranged in a staggered manner to prevent the copper clad laminate from deforming, so that the detection mechanism (2) can detect the flatness of the copper foil on the upper and lower surfaces of the copper clad laminate; The spacing support mechanism comprises a rotating block (41), a rotating rod (42) and a pressing plate (43); two mounting grooves (44) are symmetrically provided on the mounting block (3); the rotating blocks (41) are evenly spaced and installed in the mounting grooves (44); the rotating blocks (41) in the two mounting grooves (44) on the mounting block (3) are arranged alternately; the rotating rod (42) is rotatably connected to the rotating block (41); the pressing plate (43) is rotatably connected to the rotating rod (42); a synchronous gear (45) is fixedly connected to the rotating rod (42); a synchronous rack (46) is provided in the mounting groove (44); the synchronous rack (46) is meshed with the synchronous gear (45); a pushing electric push rod (47) is fixedly connected in the mounting groove (44); the pushing electric push rod (47) pushes the synchronous rack (46) to move; a supporting rod (48) is fixedly connected to the mounting block (3); The rotating block (41) is slidably connected in the mounting groove (44). 2. A copper clad laminate surface flatness detection device according to claim 1, characterized in that: a synchronization block (5) is slidably connected in the mounting groove (44); a synchronization groove (51) is provided in the synchronization block (5); the synchronization rack (46) is slidably connected in the synchronization groove (51); a return spring (52) is fixedly connected between the synchronization block (5) and the synchronization rack (46); an opening (53) is provided on the mounting block (3); a pull rod (54) is threadedly connected to the synchronization block (5); one end of the pull rod (54) is rotatably connected to the synchronization rack (46), and the other end is exposed from the opening (53). 3. A copper clad laminate surface flatness detection device according to claim 2, characterized in that: a rotating groove (6) is provided on the rotating block (41); an adjusting block (61) is rotatably connected in the rotating groove (6), and a push rod (62) is spirally fitted in the rotating groove (6); an adjusting groove (63) is provided in the push rod (62); the adjusting block (61) is slidably connected in the adjusting groove (63); the end of the push rod (62) away from the adjusting block (61) is arranged in a square shape; a square groove (64) is provided on the adjusting block (61); the push rod (62) can be inserted into the square groove (64). 4. A copper clad laminate surface flatness detection device according to claim 3, characterized in that: a detection block (55) is fixedly connected to the output end of the push electric push rod (47); a detection groove (56) is opened on the detection block (55); a detection pressure sensor (57) is fixedly connected in the detection groove (56), and a connecting block (58) is slidably connected in the detection groove (56); the connecting block (58) is fixedly connected to the synchronization block (5), and a detection spring (59) is fixedly connected between the connecting block (58) and the detection pressure sensor (57). 5. A copper-clad laminate surface flatness detection device according to claim 4, characterized in that: telescopic plates (65) are slidably connected to both sides of the pressing plate (43); the same flexible block (66) is fixedly connected to the two telescopic plates (65); an adjusting rod (67) is rotatably connected to the pressing plate (43); both ends of the adjusting rod (67) are provided with threads with opposite rotation directions, and the two ends of the adjusting rod (67) are threadedly matched with the two telescopic plates (65). 6. The copper-clad laminate surface flatness detection device according to claim 5, characterized in that a support plate (68) is rotatably connected to the telescopic plate (65). 7. A copper-clad laminate surface flatness detection device according to claim 6, characterized in that a torsion spring (69) is fixedly connected between the support plate (68) and the telescopic plate (65).