CN115752352A - Copper-clad plate surface flatness detection equipment - Google Patents

Abstract

The invention relates to the technical field of copper-clad plate detection, in particular to copper-clad plate surface flatness detection equipment. The invention provides copper clad laminate surface flatness detection equipment capable of clamping copper clad laminates of different sizes. A copper-clad plate surface flatness detection device comprises a base, a fixed frame, a placing frame, a telescopic frame, a flatness meter, a fixed rod, a detector and the like; the base upside is connected with the mount, and sliding connection has the frame of placing on the mount, and the mount top rear side rotation type is connected with the expansion bracket, is connected with the degree number table on the expansion bracket, and the left side is connected with the dead lever in the degree number table, and sliding connection has the detector between dead lever and the degree number table. According to the invention, the second supporting frame is manually moved by people, so that the second supporting frame drives the clamping device to move through the second compression spring, and when the clamping device moves to a proper position, people stop the second supporting frame, so that copper-clad plates of different sizes can be conveniently clamped, and the application range is wider.

Description

Copper-clad plate surface flatness detection equipment

Technical Field

The invention relates to the technical field of copper-clad plate detection, in particular to copper-clad plate surface flatness detection equipment.

Background

Copper-clad plate mainly used processing manufacturing circuit board is electronic industry's base material, and after the copper-clad plate was accomplished in production, people can carry out a series of detections to the copper-clad plate, including surface flatness detecting, the manufacturing quality of circuit board is decided to the roughness on copper-clad plate surface, and people use check out test set to detect copper-clad plate surface usually, however, current detection device still has following problem when using: the existing detection device can clamp the copper-clad plates when in use, but the clamping parts are difficult to clamp the copper-clad plates with different sizes, so that the copper-clad plates with different sizes are inconvenient to detect, and the use requirements of people are difficult to meet, therefore, a detection device needs to be designed.

The copper-clad plate surface flatness detection equipment capable of clamping copper-clad plates of different sizes is designed so as to achieve the effect of overcoming the defect that the existing detection device is difficult to clamp the copper-clad plates of different sizes when in use.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides copper-clad plate surface flatness detection equipment capable of clamping copper-clad plates with different sizes so as to overcome the defect that the existing detection device is difficult to clamp the copper-clad plates with different sizes.

In order to achieve the above purpose, the invention is realized by the following scheme: the utility model provides a copper-clad plate surface flatness check out test set, including:

the upper side of the base is connected with the fixed frame;

the fixing frame is connected with the placing frame in a sliding manner;

the rear side of the top of the fixed frame is rotatably connected with an expansion frame;

the expansion bracket is connected with a scale meter;

the fixing rod is connected to the left side in the degree meter;

the detector is connected between the fixed rod and the degree meter in a sliding manner;

the first compression spring is connected between the detector and the thermometer and wound on the lower side of the fixed rod;

the upper side of the front part of the detector is connected with a pointer which is in sliding connection with a degree meter;

the measuring range adjusting mechanism is arranged between the placing frame and the fixing frame and used for expanding the detection range;

a clamping mechanism is arranged in the placing frame and moves to clamp the copper-clad plate.

As an improvement of the above aspect, the measurement range adjusting mechanism includes:

the slider is connected with the front side of the placing frame and is connected with the fixed frame in a sliding way;

the rear side of the right part of the fixing frame is connected with the fixer;

the fixer is rotatably connected with the screw rod;

the screw block is connected with the screw rod in a threaded manner, and the slider on the right side is connected with the nut block.

As an improvement of the above aspect, the clamping mechanism includes:

the middle parts of the left part and the right part in the placing frame are both connected with the first supporting frame;

the first supporting frames are connected with the second supporting frames in a sliding mode;

the second supporting frame is connected with a copper-clad plate in a sliding mode;

and the second compression spring is connected between the left clamping device and the left second supporting frame, and the second compression spring is connected between the right clamping device and the right second supporting frame.

As the improvement of the scheme, the device also comprises a convex marking mechanism for marking the convex part of the copper-clad plate, wherein the convex marking mechanism comprises:

the left side of the upper part of the detector is connected with a pushing block;

the left side in the dial gauge is connected with the first fixed shaft;

the first fixed shaft is rotatably connected with the rotating frame;

the left part of the degree meter is connected with the second fixed shaft;

the second fixed shaft is connected with a second marker in a sliding way, and the second marker is connected with the rotating frame in a sliding way;

and a third compression spring is connected between the first marker and the second fixed shaft and wound on the second fixed shaft.

As an improvement of the above scheme, the clamping device further comprises a clamping width adjusting mechanism for clamping the second supporting frame, and the clamping width adjusting mechanism comprises:

the top of each second supporting frame is connected with a third fixing shaft;

the clamping blocks are connected to the two third fixing shafts in a sliding mode, and clamping grooves are formed in the first supporting frame;

and a fourth compression spring is connected between the clamping block on the left side and the second supporting frame on the left side, a fourth compression spring is connected between the clamping block on the right side and the second supporting frame on the right side, and the fourth compression spring is wound on the third fixing shaft.

As an improvement of the proposal, the copper-clad plate inner concave marking device also comprises an inner concave marking mechanism used for marking the groove of the copper-clad plate, the concave marking mechanism comprises:

the lower side of the right part of the degree meter is connected with a fourth fixed shaft;

the fourth fixed shaft is connected with a second marker in a sliding way;

and a fifth compression spring is connected between the second marker and the fourth fixed shaft, and is wound on the fourth fixed shaft.

As the improvement of the scheme, the automatic clamping device further comprises a driving mechanism for realizing automatic clamping, and the driving mechanism comprises:

the upper side of the right part of the detector is connected with a lower pressing frame;

the right part of the degree meter is connected with the fifth fixed shaft;

the fifth fixing shaft is connected with an extrusion frame in a sliding manner, and the extrusion frame is connected with the second marker in a sliding manner;

and a sixth compression spring is connected between the extrusion frame and the fifth fixed shaft and wound on the fifth fixed shaft.

As an improvement of the scheme, the front side of the screw rod is provided with an anti-skid rubber sleeve.

The invention has the advantages that: 1. according to the invention, the second supporting frame is manually moved by people, so that the second supporting frame drives the clamping device to move through the second compression spring, and when the clamping device moves to a proper position, people stop the second supporting frame, so that copper-clad plates with different sizes can be conveniently clamped, and the application range is wider;

2. the detector is moved by manually moving the degree meter by people, and then the telescopic frame can be rotated by people, so that the degree meter and the detector rotate, the detector rotates to detect the copper-clad plate, and the arc-shaped detection effect is realized;

3. the detector moves upwards to drive the pushing block to move upwards, and when the pushing block moves upwards to contact with the rotating frame, the rotating frame rotates, so that the first marker moves downwards to mark the copper-clad plate, and the marking effect is achieved.

Drawings

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

Fig. 2 is a schematic perspective view of a part of a first embodiment of the present invention.

Fig. 3 is a schematic perspective view of a part of a second embodiment of the present invention.

Fig. 4 is a schematic perspective view of a measuring range adjusting mechanism according to the present invention.

Fig. 5 is a schematic perspective view of the clamping mechanism of the present invention.

FIG. 6 is a perspective view of the raised marking mechanism of the present invention.

Fig. 7 is a schematic perspective view of a first clamping width adjusting mechanism of the present invention.

Fig. 8 is a schematic perspective view of a second clamping width adjustment mechanism of the present invention.

Fig. 9 is a schematic perspective view of the concave marking mechanism of the present invention.

Fig. 10 is a schematic three-dimensional structure of the driving mechanism of the present invention.

Wherein: 1: base, 2: mount, 3: placing frame, 4: expansion bracket, 5: degree table, 6: detector, 7: fixing rod, 71: first compression spring, 72: pointer, 8: measurement range adjustment mechanism, 81: slider, 82: nut block, 83: screw, 84: holder, 9: clamping mechanism, 91: first support frame, 92: second support frame, 93: second compression spring, 94: clamper, 10: outward convex marking mechanism, 101: push block, 102: first fixed shaft, 103: turret, 104: first marker, 105: second fixed shaft, 106: third compression spring, 11: clamping width adjusting mechanism, 111: third fixed shaft, 112: a latch, 113: card slot, 114: fourth compression spring, 12: indent marking mechanism, 121: fourth fixed shaft, 122: fifth compression spring, 123: second marker, 13: carry-over mechanism, 131: hold-down frame, 132: sixth compression spring, 133: fifth fixed shaft, 134: and (4) extruding the frame.

Detailed Description

The invention is further described with reference to the following drawings and detailed description:

example 1

The utility model provides a cover copper sheet surface flatness check out test set, now refer to fig. 1, fig. 2, fig. 3 and fig. 6, including base 1, mount 2, place frame 3, expansion bracket 4, the number of degrees table 5, detector 6, dead lever 7, first compression spring 71, pointer 72, measuring range adjustment mechanism 8 and clamping mechanism 9, base 1 upside welding has mount 2, sliding connection places frame 3 on mount 2, 2 top rear sides of mount are connected with expansion bracket 4, be connected with number of degrees table 5 on the expansion bracket 4, left side welding has dead lever 7 in the number of degrees table 5, sliding connection has detector 6 between dead lever 7 and the number of degrees table 5, be connected with first compression spring 71 between detector 6 and the number of degrees table 5, first compression spring 71 is around 7 downside of dead lever, detector 6 front portion upside is connected with pointer 72, pointer 72 and number of degrees table 5 sliding connection, it is equipped with measuring range adjustment mechanism 8 to place between frame 3 and the mount 2, it is equipped with clamping mechanism 9 to place in the frame 3.

Referring now to fig. 1 and 4, the measuring range adjusting mechanism 8 includes a slider 81, a nut block 82, a screw rod 83 and a fixer 84, the front side of the placement frame 3 is connected with two sliders 81, the slider 81 is connected with the fixing frame 2 in a sliding manner, the right rear side of the fixing frame 2 is welded with the fixer 84, the fixer 84 is connected with the screw rod 83 in a rotating manner, the front side of the screw rod 83 is provided with an anti-skid rubber sleeve, the screw rod 83 is connected with the nut block 82 in a threaded manner, and the slider 81 on the right side is connected with the nut block 82.

Referring to fig. 1 and 5, the clamping mechanism 9 includes a first supporting frame 91, a second supporting frame 92, a second compression spring 93 and a clamp 94, the first supporting frame 91 is welded in the middle of the left and right portions of the placing frame 3, the second supporting frame 92 is connected to each of the two first supporting frames 91 in a sliding manner, the clamp 94 is connected to each of the two second supporting frames 92 in a sliding manner, the clamp 94 is connected to the placing frame 3 in a sliding manner, the second compression spring 93 is connected between the left clamp 94 and the left second supporting frame 92, and the second compression spring 93 is connected between the right clamp 94 and the right second supporting frame 92.

When people need to detect the surface flatness of the copper clad laminate, people can use the copper clad laminate surface flatness detection device, the detector 6 in the initial state is in contact with the placing frame 3, firstly, people manually move the second supporting frame 92 according to the size of the copper clad laminate to enable the second supporting frame 92 to drive the clamp 94 to move through the second compression spring 93, when the clamp 94 moves to a proper position, people stop moving the second supporting frame 92, then, people manually move the detector 6 upwards to enable the pointer 72 to move upwards to enable the first compression spring 71 to be stretched, then, people manually move the clamp 94 outwards to enable the second compression spring 93 to be compressed, when the clamp 94 moves to a proper position, people place the copper clad laminate in the placing frame 3 and between the two clamps 94, after the placing is completed, people release the clamp 94 and the detector 6, so that the first compression spring 71 drives the detector 6 to move downwards, thereby the pointer 72 moves downwards, then the detector 6 is contacted with the copper-clad plate, the first compression spring 71 is still in a stretched state, meanwhile, the second compression spring 93 resets and drives the clamping device 94 to move inwards to be contacted with the copper-clad plate, thereby the clamping effect is realized, then when people need to detect the surface of the copper-clad plate in a circular arc shape, people can manually move the dial indicator 5, so that the expansion bracket 4 can be adaptively expanded or shortened, thereby the detector 6 moves, when the detector 6 moves to a proper position, people manually rotate the expansion bracket 4, thereby the dial indicator 5 and the detector 6 rotate, when the detector 6 does not move up and down in the rotating process, the surface of the copper-clad plate is flat, when the detector 6 is contacted with the convex part on the surface of the copper-clad plate, the detector 6 is adaptively moved upward so that the pointer 72 is moved upward, the first compression spring 71 is stretched, one can know the height of the protrusion according to the degree of the pointer 72 pointing to the degree table 5, then when the detector 6 is moved to the flat copper clad surface, the first compression spring 71 drives the detector 6 to move downward so that the pointer 72 moves downward, and when the detector 6 is in contact with the groove portion of the copper clad surface, the first compression spring 71 drives the detector 6 to move downward so that the pointer 72 moves downward, one can know the height of the groove according to the degree of the pointer 72 pointing to the degree table 5, then when the detector 6 is moved to the flat copper clad surface, the detector 6 and the pointer 72 move upward so that the first compression spring 71 continues to be stretched, and when the circular arc detection is completed, one can reversely rotate the telescopic frame 4 to a proper position, so that the dial indicator 5 and the detector 6 rotate reversely, when people need to vertically detect the surface of the copper clad plate, people can manually rotate the lead screw 83 after moving the detector 6 to a proper position according to the steps, so that the nut block 82 moves backwards, the slider 81 and the placing frame 3 move backwards, so that the copper clad plate moves backwards, then the detector 6 detects the surface of the copper clad plate according to the steps, when the detection is completed, people manually rotate the lead screw 83 reversely, so that the nut block 82 moves forwards, so that the slider 81 and the placing frame 3 move forwards, so that the copper clad plate moves forwards, when the placing frame 3 moves to a proper position, people stop rotating the lead screw 83, then people manually move the clamp 94 to a proper position outwards, so that the second compression spring 93 is compressed, and meanwhile, people manually move the detector 6 upwards, so that the pointer 72 moves upwards, the first compression spring 71 is stretched, then people take out the copper-clad plate which is detected, and after the copper-clad plate is taken out, people loosen the clamp 94 and the detector 6, so that the second compression spring 93 resets to drive the clamp 94 to move inwards to reset, and the first compression spring 71 resets to drive the pointer 72 and the detector 6 to move downwards to reset.

Example 2

On the basis of embodiment 1, referring to fig. 1, 2 and 6, the portable outer marker device further includes an outer convex marking mechanism 10, wherein the outer convex marking mechanism 10 includes a pushing block 101, a first fixing shaft 102, a rotating frame 103, a first marker 104, a second fixing shaft 105 and a third compression spring 106, the pushing block 101 is connected to the left side of the upper portion of the detector 6, the first fixing shaft 102 is welded to the left side of the inner portion of the dial indicator 5, the rotating frame 103 is rotatably connected to the first fixing shaft 102, the pushing block 101 contacts the rotating frame 103 after moving, the second fixing shaft 105 is connected to the left portion of the dial indicator 5, the first marker 104 is slidably connected to the rotating frame 103, the third compression spring 106 is connected between the first marker 104 and the second fixing shaft 105, and the third compression spring 106 is wound on the second fixing shaft 105.

Referring to fig. 1, 7 and 8, the clamping device further includes a clamping width adjusting mechanism 11, the clamping width adjusting mechanism 11 includes a third fixing shaft 111, eight clamping blocks 112 and a fourth compression spring 114, the third fixing shaft 111 is welded at the top of each of the two second supporting frames 92, the two third fixing shafts 111 are connected with the clamping blocks 112 in a sliding manner, the two first supporting frames 91 are provided with four clamping grooves 113, the number of the clamping grooves 113 is eight, the left clamping block 112 contacts with the left clamping groove 113, the right clamping block 112 contacts with the right clamping groove 113, the fourth compression spring 114 is connected between the left clamping block 112 and the left second supporting frame 92, the fourth compression spring 114 is connected between the right clamping block 112 and the right second supporting frame 92, and the fourth compression spring 114 is wound on the third fixing shaft 111.

Referring to fig. 1, 2 and 9, the indent marking mechanism 12 is further included, the indent marking mechanism 12 includes a fourth fixing shaft 121, a fifth compression spring 122 and a second marker 123, the fourth fixing shaft 121 is welded to the lower right side of the dial gauge 5, the second marker 123 is slidably connected to the fourth fixing shaft 121, the fifth compression spring 122 is connected between the second marker 123 and the fourth fixing shaft 121, and the fifth compression spring 122 is wound on the fourth fixing shaft 121.

Referring to fig. 1, 2 and 10, the optical fiber temperature measuring device further includes a driving mechanism 13, the driving mechanism 13 includes a lower pressing frame 131, a sixth compression spring 132, a fifth fixing shaft 133 and an extruding frame 134, the lower pressing frame 131 is connected to the upper side of the right portion of the detector 6, the fifth fixing shaft 133 is welded to the right portion of the odometer 5, the extruding frame 134 is slidably connected to the fifth fixing shaft 133, the extruding frame 134 is slidably connected to the second marker 123, the lower pressing frame 131 contacts the extruding frame 134 after moving, the sixth compression spring 132 is connected between the extruding frame 134 and the fifth fixing shaft 133, and the sixth compression spring 132 is wound on the fifth fixing shaft 133.

When detector 6 contacts with the convex part on the copper-clad plate, detector 6 moves upward and drives pushing block 101 to move upward, when pushing block 101 moves upward and contacts with rotating frame 103, rotating frame 103 rotates, thereby make first marker 104 move downward, make third compression spring 106 compressed, first marker 104 marks on the copper-clad plate afterwards, thereby the effect of marking has been realized, detector 6 moves downward and drives pushing block 101 to move downward, when pushing block 101 moves downward and keeps away from rotating frame 103, third compression spring 106 resets and drives first marker 104 to move upward and reset, make rotating frame 103 counter-rotation.

When people need move the second carriage 92 according to the size adaptability of the copper-clad plate, people can manually move the fixture block 112 upwards, thereby enabling the fourth compression spring 114 to be stretched, when the fixture block 112 moves upwards to be away from the clamping groove 113, people can adaptively move the second carriage 92, thereby enabling the clamping device 94 to move, when the clamping device 94 moves to a proper position, people loosen the fixture block 112, thereby enabling the fourth compression spring 114 to reset to drive the fixture block 112 to move downwards to the clamping groove 113, thereby realizing the adjusting effect, and facilitating the clamping of copper-clad plates with different sizes.

When the detector 6 detects that the surface of the copper-clad plate has a groove part, people manually move the second marker 123 downwards, so that the fifth compression spring 122 is compressed, when the second marker 123 moves downwards to contact with the copper-clad plate, the second marker 123 marks on the copper-clad plate, and then people release the second marker 123, so that the fifth compression spring 122 resets to drive the second marker 123 to move upwards for resetting.

The detector 6 moves downwards to drive the lower pressing frame 131 to move downwards, when the lower pressing frame 131 moves downwards to contact with the extrusion frame 134, the lower pressing frame 131 drives the extrusion frame 134 to move rightwards, so that the sixth compression spring 132 is compressed, the second marker 123 moves downwards, the automatic marking effect is achieved, manpower is saved, the detector 6 moves upwards to drive the lower pressing frame 131 to move upwards, when the lower pressing frame 131 moves upwards to be far away from the extrusion frame 134, the sixth compression spring 132 resets to drive the extrusion frame 134 to move leftwards, and the second marker 123 moves upwards.

Various other modifications and changes may occur to those skilled in the art based on the foregoing teachings and concepts, and all such modifications and changes are intended to be included within the scope of the appended claims.

Claims (8)

1. The utility model provides a copper-clad plate surface flatness check out test set which characterized in that, including:

the device comprises a base (1) and a fixed frame (2), wherein the fixed frame (2) is connected to the upper side of the base (1);

the fixing frame (2) is connected with the placing frame (3) in a sliding way;

the rear side of the top of the fixed frame (2) is rotatably connected with the telescopic frame (4);

the degree meter (5) is connected to the telescopic frame (4);

the fixing rod (7) is connected to the left side in the dial indicator (5);

the detector (6) is connected between the fixed rod (7) and the degree meter (5) in a sliding manner;

the first compression spring (71) is connected between the detector (6) and the degree meter (5), and the first compression spring (71) is wound on the lower side of the fixing rod (7);

the upper side of the front part of the detector (6) is connected with the pointer (72), and the pointer (72) is connected with the thermometer (5) in a sliding manner;

the measuring range adjusting mechanism (8) is arranged between the placing frame (3) and the fixing frame (2), and the measuring range adjusting mechanism (8) is used for expanding the detection range;

a clamping mechanism (9) is arranged in the placing frame (3), and the clamping mechanism (9) moves to clamp the copper-clad plate.

2. The apparatus for inspecting flatness of a copper-clad plate surface according to claim 1, wherein the measuring range adjusting mechanism (8) comprises:

the slider (81) is connected to the front side of the placing frame (3), and the slider (81) is connected with the fixed frame (2) in a sliding manner;

the fixer (84) is connected with the rear side of the right part of the fixing frame (2);

the screw rod (83) is rotatably connected to the fixer (84);

the screw rod (83) is connected with the nut block (82) in a threaded manner, and the slider (81) on the right side is connected with the nut block (82).

3. The apparatus for inspecting flatness of a copper-clad plate surface according to claim 2, wherein the clamping mechanism (9) comprises:

the middle parts of the left part and the right part in the placing frame (3) are connected with the first supporting frame (91);

the first supporting frames (91) are connected with the second supporting frames (92) in a sliding mode; the clamping devices (94) are connected to the second supporting frame (92) in a sliding mode, the clamping devices (94) are connected to the placing frame (3) in a sliding mode, and the clamping devices (94) clamp the copper-clad plate after moving;

and a second compression spring (93), wherein the second compression spring (93) is connected between the left clamp (94) and the left second support frame (92), and the second compression spring (93) is connected between the right clamp (94) and the right second support frame (92).

4. The copper-clad plate surface flatness detection equipment according to claim 3, further comprising a convex marking mechanism (10) for marking the convex part of the copper-clad plate, wherein the convex marking mechanism (10) comprises:

the pushing block (101) is connected to the left side of the upper part of the detector (6);

the left side in the thermometer (5) is connected with the first fixed shaft (102);

the rotating frame (103), the first fixed shaft (102) is connected with the rotating frame (103) in a rotating mode;

the left part of the degree meter (5) is connected with the second fixed shaft (105);

the first marker (104) is connected to the second fixed shaft (105) in a sliding mode, and the first marker (104) is connected with the rotating frame (103) in a sliding mode;

and a third compression spring (106), wherein the third compression spring (106) is connected between the first marker (104) and the second fixing shaft (105), and the third compression spring (106) is wound on the second fixing shaft (105).

5. The copper-clad plate surface flatness detecting apparatus according to claim 4, further comprising a clamping width adjusting mechanism (11) for clamping the second supporting frame (92), the clamping width adjusting mechanism (11) comprising:

the top of each second supporting frame (92) is connected with a third fixed shaft (111);

the clamping blocks (112) are connected to the two third fixing shafts (111) in a sliding mode, and clamping grooves (113) are formed in the first supporting frame (91);

and a fourth compression spring (114) is connected between the fixture block (112) on the left side and the second supporting frame (92) on the left side, the fourth compression spring (114) is connected between the fixture block (112) on the right side and the second supporting frame (92) on the right side, and the fourth compression spring (114) is wound on the third fixing shaft (111).

6. The copper-clad plate surface flatness detection equipment according to claim 5, further comprising an indent marking mechanism (12) for marking the copper-clad plate groove, wherein the indent marking mechanism (12) comprises:

the lower side of the right part of the degree meter (5) is connected with the fourth fixed shaft (121);

the second marker (123) is connected with the fourth fixed shaft (121) in a sliding way; and a fifth compression spring (122) is connected between the second marker (123) and the fourth fixed shaft (121), and the fifth compression spring (122) is wound on the fourth fixed shaft (121).

7. The copper clad plate surface flatness detection apparatus according to claim 6, further comprising a driving mechanism (13) for realizing automatic clamping, wherein the driving mechanism (13) comprises:

the lower pressing frame (131) is connected with the upper side of the right part of the detector (6);

the right part of the degree meter (5) is connected with the fifth fixed shaft (133);

the fifth fixing shaft (133) is connected with the extrusion frame (134) in a sliding mode, and the extrusion frame (134) is connected with the second marker (123) in a sliding mode;

and the sixth compression spring (132), the sixth compression spring (132) is connected between the extrusion frame (134) and the fifth fixed shaft (133), and the sixth compression spring (132) is wound on the fifth fixed shaft (133).

8. The copper-clad plate surface flatness detection apparatus according to claim 2, wherein the lead screw (83) is provided with an anti-slip rubber sleeve on the front side.

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