WO2020173158A1 - Procédé de perçage de carte de circuit imprimé et appareil de perçage - Google Patents

Procédé de perçage de carte de circuit imprimé et appareil de perçage Download PDF

Info

Publication number
WO2020173158A1
WO2020173158A1 PCT/CN2019/121608 CN2019121608W WO2020173158A1 WO 2020173158 A1 WO2020173158 A1 WO 2020173158A1 CN 2019121608 W CN2019121608 W CN 2019121608W WO 2020173158 A1 WO2020173158 A1 WO 2020173158A1
Authority
WO
WIPO (PCT)
Prior art keywords
tool
knife
presser foot
spindle
tip
Prior art date
Application number
PCT/CN2019/121608
Other languages
English (en)
Chinese (zh)
Inventor
常远
Original Assignee
维嘉数控科技(苏州)有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from CN201911076159.0A external-priority patent/CN111629517B/zh
Application filed by 维嘉数控科技(苏州)有限公司 filed Critical 维嘉数控科技(苏州)有限公司
Publication of WO2020173158A1 publication Critical patent/WO2020173158A1/fr

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23BTURNING; BORING
    • B23B47/00Constructional features of components specially designed for boring or drilling machines; Accessories therefor
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23QDETAILS, COMPONENTS, OR ACCESSORIES FOR MACHINE TOOLS, e.g. ARRANGEMENTS FOR COPYING OR CONTROLLING; MACHINE TOOLS IN GENERAL CHARACTERISED BY THE CONSTRUCTION OF PARTICULAR DETAILS OR COMPONENTS; COMBINATIONS OR ASSOCIATIONS OF METAL-WORKING MACHINES, NOT DIRECTED TO A PARTICULAR RESULT
    • B23Q11/00Accessories fitted to machine tools for keeping tools or parts of the machine in good working condition or for cooling work; Safety devices specially combined with or arranged in, or specially adapted for use in connection with, machine tools
    • B23Q11/08Protective coverings for parts of machine tools; Splash guards
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23QDETAILS, COMPONENTS, OR ACCESSORIES FOR MACHINE TOOLS, e.g. ARRANGEMENTS FOR COPYING OR CONTROLLING; MACHINE TOOLS IN GENERAL CHARACTERISED BY THE CONSTRUCTION OF PARTICULAR DETAILS OR COMPONENTS; COMBINATIONS OR ASSOCIATIONS OF METAL-WORKING MACHINES, NOT DIRECTED TO A PARTICULAR RESULT
    • B23Q3/00Devices holding, supporting, or positioning work or tools, of a kind normally removable from the machine
    • B23Q3/155Arrangements for automatic insertion or removal of tools, e.g. combined with manual handling
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K3/00Apparatus or processes for manufacturing printed circuits

Definitions

  • a PCB drilling method and drilling method prepare
  • This application relates to the technical field of PCB processing, for example, to a PCB drilling method and drilling equipment.
  • Background technique
  • the spindle of the PCB drilling machine and the chip suction cover in the related technology are connected to the spindle clamp.
  • the bottom of the spindle is used to install drilling tools.
  • the Z-axis motor drives the spindle clamp to move up and down to achieve drilling.
  • the chip suction cover sucks chips.
  • the hood cylinder is connected to the spindle clamp, and the dust hood is connected to the vacuum pipeline through the suction pipe elbow to suck away the dust generated during drilling.
  • the presser foot is fixed at the bottom of the chip suction cover, and the presser foot is used to press the workpiece when drilling; the bottom of the chip suction cover is provided with a through hole, and the presser foot is connected to the through hole to form a cavity together with the chip suction cover; At the bottom of the spindle and inside the presser foot.
  • the presser foot presses the workpiece, and sucks the dust into the cavity from the inner side of the presser foot and sucks it away through the vacuum line.
  • the chip suction cover and the spindle need to maintain the same relative position.
  • This relative position is usually defined as the distance from the presser foot to the tip of the tool.
  • the distance from the presser foot to the tip of the tool is an important indicator that affects the accuracy and speed of drilling.
  • the setting value is usually adjusted to about l-2mm, and it will remain unchanged after setting. , All tools are processed at this distance. In order to ensure a constant distance from the presser foot to the tool tip, all tools are set to the same length.
  • the PCB drilling tool in the related technology is divided into three parts from top to bottom (refer to Figure 1 and Figure 2): clamping section 2’, transition section 3’, and processing section 4’.
  • the clamping section 2' is clamped in the spindle chuck, usually with a standard diameter and length.
  • a plastic collar 1' is installed at the standard position of the tool, above the collar 1'
  • To clamp the length inside the chuck (clamping section 2') outside the collar 1'is the length of the exposed chuck (including the transition section 3'and the processing section 4').
  • Machining section 4' is the part with cutting edges and chip flutes for machining.
  • the middle is the transition section 3'.
  • the length of the processing section 4' varies with the diameter. Generally, the smaller the diameter, the tool has poor rigidity. The shorter the length of the processing section 4', the longer the intermediate transition section 3'.
  • the transition section 3'in the middle of the tool has no positive effect on the drilling process. If the length of the transition section 3'can be reduced, the length of the tool's overall exposed chuck can be reduced, so that the deflection error during the height drilling process can be reduced, and the drilling accuracy can be improved. In addition, reducing the length of the redundant transition section 3'can also reduce the length of the tool, and also reduce the cost of the tool.
  • most of the tools used for PCB drilling are micro-hole drills with a small diameter (refer to Figure 1), but a small part are drills with a relatively large diameter (refer to Figure 2). Generally speaking, the blade of a large knife The length of the knife is longer, and the blade length of the small knife is shorter.
  • the tool lengths of the big knife and the small knife need to be maintained at a uniform size, which leads to It is not compatible with drilling tools of different lengths, and tools with large diameters and long processing sections must be accommodated.
  • the length of the micro drill needs to be increased, and changing the length of the micro drill has a great impact on the accuracy and cost of PCB drilling.
  • the present application provides a PCB drilling method, which is compatible with tools of different lengths, improves drilling accuracy, and reduces drilling costs.
  • a PCB drilling method includes the following steps:
  • Step S10 the tool changing mechanism grabs the tool and changes the tool
  • Step S20 Determine whether the tool is a small knife or a big knife
  • Step S30 Taking the standard length of the small knife L1 or the standard length of the big knife L2 as a reference, the system automatically configures the relative position of the presser foot and the tool tip;
  • Step S40 drilling holes corresponding to the tool
  • Step S50 Repeat the above steps S10-S40 until all the hole positions are processed.
  • step S20 determining that the tool is a small knife or a large knife includes:
  • the diameter of the tool is greater than d, it is a big tool
  • the diameter of the tool is less than or equal to d, it is a small knife.
  • step S30 after the system automatically configures the relative position of the presser foot and the tool tip, it also includes: taking the standard length of the small knife L1 or the standard length of the big knife L2 as a reference, the system automatically configures the tool measuring height.
  • the method further includes:
  • the system automatically configures the relative position of the presser foot and the tool tip in step S30 as follows: configure the relative position of the presser foot and the tool tip by adjusting the height of the chip suction cover.
  • the height adjustment of the dust suction cover is:
  • the tool is a big knife, adjust the position of the chip suction cover to the first height
  • the tool is a small knife, adjust the position of the chip suction cover to the second height
  • the difference between the first height and the second height is L2-L1.
  • the position of the dust suction cover is adjusted by a multi-stroke cylinder or electric cylinder.
  • step S30 automatically configures the relative position of the presser foot and the tool tip as follows: configure the relative position of the presser foot and the tool tip by adjusting the height of the spindle.
  • the height of the adjustment spindle is:
  • the difference between the first distance and the second distance is L2-L1.
  • This application also provides a PCB drilling method, including the following steps:
  • Step S10 the tool changing mechanism grabs the tool and changes the tool
  • Step S20 Determine whether the tool is a small knife or a big knife
  • Step S30 When the tool is a small knife, automatically configure the relative position of the presser foot and the tip of the tool based on the standard length L1 of the small knife; when the tool is a large knife, take the standard length L2 of the large knife as the reference, Automatically configure the relative position of the presser foot and the tip of the tool;
  • Step S40 Drill holes corresponding to the tool.
  • step S20 determining that the tool is a small knife or a large knife includes:
  • the standard diameter of the tool is less than or equal to d, it is a small knife
  • d is the critical value of the standard diameter of the big knife and the small knife.
  • step S20 determining that the tool is a small knife or a large knife includes:
  • the standard length of the tool is less than or equal to L, it is a small knife
  • L is the critical value of the standard length of the big knife and the small knife.
  • automatically configuring the relative position of the presser foot and the tip of the tool includes: adjusting the height of the chip suction cover to configure the relative position of the presser foot and the tip of the tool.
  • the adjusting the height of the dust suction cover includes:
  • the tool is a big knife, adjust the position of the chip suction cover to the first height
  • the tool is a small knife, adjust the position of the chip suction cover to the second height; Wherein, the difference between the first height and the second height is L2-LL
  • the position of the dust suction cover is adjusted by a multi-stroke cylinder or electric cylinder.
  • automatically configuring the relative position of the presser foot and the tip of the tool includes: configuring the relative position of the presser foot and the tip of the tool by adjusting the height of the spindle.
  • the adjusting the height of the main shaft includes:
  • the difference between the first distance and the second distance is L2-L1.
  • step S30 before the automatic configuration of the relative positions of the presser foot and the tip of the tool, the method further includes:
  • dl is the standard diameter of the small knife
  • d2 is the standard diameter of the big knife.
  • the method further includes:
  • the tool is automatically configured relative to the machine table. the height of.
  • This application also provides a drilling device, which is compatible with tools of different lengths, improves drilling accuracy, and reduces drilling costs.
  • a drilling device the device adopts the aforementioned PCB drilling method, the drilling device includes: a spindle clamp configured to move relative to the PCB board to be processed;
  • a chip suction cover slidably connected to the spindle clamp, a ring-shaped presser foot is provided at the bottom of the chip suction cover; a main shaft is connected to the spindle clamp, and the tool is connected to the bottom of the main shaft and is located inside the presser foot; and
  • a drive assembly is connected to the spindle clamp and the output end is connected to the chip suction cover or the spindle, and the drive assembly is configured to adjust the distance from the presser foot to the tip of the tool.
  • This application also provides a drilling device, which includes:
  • the spindle clamp is configured to move relative to the PCB board to be processed
  • a chip suction cover which is slidably connected with the spindle clamp
  • Presser foot the presser foot is arranged at the bottom of the dust suction cover, and the presser foot is ring-shaped;
  • a spindle connected with the spindle clamp
  • a cutter the cutter is connected to the spindle and is located inside the presser foot;
  • the drive assembly is connected with the spindle clamp, and the output end of the drive assembly is connected with the chip suction cover, and the drive assembly is configured to drive the chip suction cover to adjust the pressure foot to the tool The distance of the tool tip.
  • This application also provides a drilling device, which includes:
  • the spindle clamp is configured to move relative to the PCB board to be processed
  • a dust suction cover connected with the spindle clamp
  • Presser foot the presser foot is arranged at the bottom of the dust suction cover, and the presser foot is ring-shaped;
  • the main shaft is slidably connected with the main shaft clamp
  • a cutter the cutter is connected to the spindle and is located inside the presser foot;
  • the PCB drilling method includes: the tool change mechanism grabs the tool and changes the tool; judging that the tool is a small knife or a big knife; taking the standard length of the small knife L1 or the standard length L2 of the big knife as a reference, automatically configuring the presser foot and the tip of the tool The relative position of the tool; drill the hole corresponding to the tool; change the tool and repeat the above steps until the processing is completed.
  • This application establishes two different sets of benchmarks for small knives and big knives, and adjusts the distance between the presser foot and the tip of the tool according to the actual tool grabbed.
  • the tip distance of all drilling tools is from the presser foot
  • the distance is the same, and it can be compatible with tools of different lengths during processing, and because the small tool becomes shorter, the dynamic deflection under the high-speed rotation of the spindle will be reduced, and the rigidity will also increase, which will improve the accuracy of drilling.
  • reducing the length of the tool holder can also reduce the cost of the tool.
  • FIG. 1 is a schematic diagram of the structure of the knife provided in this application.
  • Figure 2 is a schematic view of the structure of the broad knife provided by the present application
  • Figure 3 is a schematic diagram of the structure of the drilling equipment provided by the present application
  • FIG. 4 is a schematic diagram of the structure of the driving assembly provided by the present application.
  • Fig. 5 is a schematic diagram from another angle of Fig. 4;
  • FIG. 6 is a cross-sectional view of part of the structure of the drilling equipment provided by the present application when it is in the tool change position
  • FIG. 7 is a cross-sectional view of the part of the structure when the drilling equipment provided by the present application is in the initial position of the knife drilling
  • Figure 8 is a cross-sectional view of part of the structure of the drilling equipment provided by the present application when it is in the initial position of the big knife drilling;
  • Figure 9 is the first flow chart of the PCB drilling method provided by this application.
  • FIG. 10 is the second flowchart of the PCB drilling method provided by this application.
  • Figure 11 is a schematic diagram of the drilling cycle of the PCB drilling method of the present application.
  • the drilling equipment includes a spindle clamp 1, a Z-axis motor 2, a chip suction cover 3, a spindle 4, and a drive assembly 5.
  • the spindle clamp 1 is connected to the Z-axis motor 2, and the Z-axis motor 2 drives the spindle clamp 1 to move, so that the spindle clamp 1 is raised and lowered relative to the PCB board to be processed;
  • the chip suction cover 3 is slidably connected to the spindle clamp 1 and the chip suction cover 3
  • An annular presser foot 6 is provided at the bottom of the presser foot 6, and the inside of the presser foot 6 communicates with the inside of the dust suction cover 3, and the dust suction cover 3 is connected to the negative pressure device through a dust suction pipe;
  • the spindle 4 is connected to the spindle clamp 1, and the tool 7 is connected to The bottom of the main shaft 4 is located inside the presser foot 6.
  • the drive assembly 5 is connected to the spindle clamp 1 and the output end of the drive assembly 5 is connected to the chip suction cover 3.
  • the drive assembly 5 is configured to adjust the distance between the presser foot 6 and the tip of the tool 7 by moving the chip suction cover 3.
  • the driving assembly 5 may be a multi-stroke cylinder or an electric cylinder, so as to provide at least two different driving positions to meet different distance adjustments.
  • the driving assembly 5 is a single-ended three-position cylinder, which includes a first cylinder 51 and a second cylinder
  • the driving assembly 5 has three driving positions, the first driving position is that the output ends of the two cylinders are not extended, the second driving position is that the output ends of one of the cylinders are extended, and the third driving position is two The output ends of the cylinders are all extended. As shown in Figure 5, the working process of the single-ended three-position cylinder is:
  • the three driving positions of the driving assembly 5 are shown in Figures 6-8, the first driving position is the tool change position (refer to Figure 6), and the second driving position is the drill of the knife.
  • the initial position of the hole (refer to Figure 7), and the third driving position is the initial position of the drill hole (refer to Figure 8).
  • the height of the spindle 4 remains unchanged.
  • the output end of the drive assembly 5 is in the first drive position;
  • the tool 7 does not expose the presser foot 6, and the tip of the tool 7 needs to keep a fixed distance from the bottom end surface of the presser foot 6. Therefore, the driving position of the output end of the driving assembly 5 is different.
  • the three positions can be 0mm stroke, 15mm stroke and 25mm stroke (the value represents the extension distance of the output end of the drive assembly 5).
  • the 0mm stroke is the tool change position
  • the 15mm stroke is the initial drilling position of the small knife
  • the 25mm stroke is the initial drilling position of the big knife.
  • a drill of the same length as in the related technology can be used at the initial position of the big knife drilling hole.
  • a tool with a length of 10mm shorter than that in the related technology can be used at the initial position of the knife hole.
  • This embodiment only takes two tools with different lengths as an example to illustrate that the drive assembly 5 has three drive positions.
  • the cylinder 51 in the drive assembly 5 can be replaced with an electric cylinder with more precise stroke adjustment. The adjustment of the position of the dust suction cover 3 through the electric cylinder enables the driving assembly 5 to have more driving positions, so as to be able to adapt to three or more types of tools 7.
  • the length of the tool with the smaller diameter does not have to be adapted to the tool with the larger diameter
  • the length of the knife can be designed to be shorter, which is beneficial to improve the rigidity and service life of the knife. And because the knife becomes shorter, the dynamic deflection under the high-speed rotation of the spindle 4 will decrease, and the rigidity will increase, which will improve the accuracy of drilling. At the same time, reducing the length of the tool holder can also reduce the cost of the tool.
  • the drive assembly 5 is connected to the spindle clamp, and the output end of the drive assembly 5 is connected to the spindle.
  • the drive assembly 5 is configured to drive the spindle to adjust the distance from the presser foot to the tip of the tool.
  • the spindle The clamp 1 and the main shaft 4 are slidably connected for relative movement.
  • an air floating structure can be arranged between the two to realize relative movement.
  • the presser foot can be fixed, and the tool can be moved by the movement of the spindle, thereby realizing the adjustment of the distance between the tip of the tool and the presser foot.
  • the drilling equipment also includes a tool magazine 8 and a tool changing mechanism.
  • the tool magazine 8 is arranged on one side of the spindle clamp 1, and a plurality of tools 7 are sequentially placed in the tool magazine 8, and the tool changing mechanism is set to
  • the tool 7 in the tool magazine 8 is installed at the bottom of the spindle 4, and the tool 7 installed at the bottom of the spindle 4 is put back in the tool magazine 8 to realize the tool change.
  • the presser foot 6 moves upward relative to the spindle 4, so that the bottom of the spindle 4 protrudes from the presser foot 6—a certain distance is exposed, which is convenient for tool change.
  • Step S10 the tool changing mechanism grabs the tool and changes the tool
  • Step S20 Judge whether the tool is a small knife or a big knife
  • Step S30 When the tool is a small knife, automatically configure the relative position of the presser foot and the tip of the tool 7 based on the standard length of the small knife L1; when the tool is a large knife, use the standard length L2 of the large knife as the reference, automatically Configure the relative position of the presser foot and the tool tip;
  • Step S40 Drill holes corresponding to the tool.
  • This application establishes two different sets of benchmarks for small knives and large knives, respectively. Adjust the distance between the presser foot 6 and the tool tip of the tool 7 according to the tool 7 actually grabbed. At the starting position of drilling, the tip of all drilling tools The distance from the presser foot is the same, and it can be compatible with tools of different lengths during processing. And because the small knife becomes shorter, the dynamic deflection under high-speed rotation of the spindle 4 will be reduced, and the rigidity will increase, thereby improving the accuracy of drilling . At the same time, reducing the length of the tool holder can also reduce the cost of the tool 7.
  • step S20 determining that the tool 7 is a small knife or a big knife includes:
  • each position in the tool magazine 8 is preset with diameter data matching the diameter of the inserted tool 7.
  • the tool changer mechanism automatically grabs the tool according to the setting program.
  • the standard diameter of the tool 7 can be automatically distinguished as being greater than d or less than or equal to d (where d is the preset standard diameter critical value of the big knife and the small knife), thereby distinguishing the big knife and the small knife.
  • all the big knives are knives of the same length (standard diameter is d2, standard length is L2), all small knives are also knives of the same length (standard diameter is dl, standard length is L1 ).
  • step S20 determining that the tool 7 is a small knife or a large knife may also include:
  • the standard length of tool 7 is less than or equal to L, it is a small knife.
  • each position in the tool magazine 8 is preset with length data that matches the length of the inserted tool 7, when the tool change mechanism automatically grabs the tool according to the setting program.
  • the standard length of the tool 7 can be automatically distinguished as being greater than L or less than or equal to L (where L is the pre-set critical value of the standard length of the large knife and the small knife), thereby distinguishing between the large knife and the small knife.
  • L is the pre-set critical value of the standard length of the large knife and the small knife
  • the standard diameter or standard length of the tool it can be preliminarily judged whether the tool is a big knife or a small knife.
  • step S20 determines that tool 7 is a small knife or a big knife, proceed to step S30.
  • the small knife is based on its standard length L1
  • the big knife is based on its standard length L2.
  • the device automatically configures the relative position of the presser foot 6 to the tip of the tool 7.
  • the presser foot 6 is arranged at the bottom of the dust suction cover 3, and the relative position of the presser foot and the tool tip can be configured by adjusting the height of the dust suction cover 3.
  • adjusting the height of the chip suction cover 3 includes: if the tool 7 is a large knife, adjusting the position of the chip suction cover 3 to the first height; if the tool 7 is a small knife, adjusting the position of the chip suction cover 3 to the first height Two heights; where the difference between the first height and the second height is (L2-L1), it should be noted that the first height and the second height are based on the table of the machine, from the table to the dust hood The distance from the bottom surface.
  • the position of the spindle 4 remains unchanged, that is, the position of the tool remains unchanged.
  • Adjusting the height of the dust suction cover 3 can keep the presser foot at a proper distance from the tool tip.
  • the difference between the first height and the second height is (L2-L1), whether it is a big knife or a small knife, the position of the presser foot from the tool tip is always the same.
  • the position of the dust hood 3 is adjusted by a multi-stroke cylinder or an electric cylinder, which can realize the adjustment of multiple positions.
  • L2-L1 refers to the difference between the standard length of the big knife L2 and the standard length of the small knife L1, that is, the calculation result of the standard length of the big knife L2 minus the standard length L1 of the small knife.
  • the relative position of the presser foot and the tip of the tool 7 can also be configured by adjusting the height of the spindle 4.
  • adjusting the height of the spindle 4 includes: if the tool 7 is a large tool, adjusting the position of the spindle 4 to a first distance; if the tool 7 is a small tool, adjusting the position of the spindle 4 to a second distance. Wherein, the difference between the first distance and the second distance is (L2-L1).
  • the first distance and the second distance are the distances from the table surface to the bottom surface of the spindle based on the table surface of the machine table.
  • the position of the chip suction cover remains unchanged, that is, the position of the presser foot remains unchanged.
  • Adjusting the height of the spindle can keep the tip of the tool at a proper distance from the presser foot.
  • the difference between the first distance and the second distance is (L2-L1), whether it is a big knife or a small knife, the position of the tip of the knife from the presser foot is always the same.
  • step S30 before automatically configuring the relative position of the presser foot 6 and the tip of the tool 7, it also includes: measuring the actual length L'and the actual diameter d'of the tool.
  • L'and d' are the actual length and actual diameter of the tool 7. Since each tool 7 has some accuracy errors during the machining process, the actual length and actual diameter of each tool 7 may be different. By measuring L’ and d’, it is possible to accurately judge whether the tool is grasped accurately.
  • the tolerance ranges mentioned above are all preset, and the values of the tolerance ranges need to be selected and set according to actual conditions.
  • the tolerance range of the above diameter is 0-0.05mm
  • the tolerance range of the length is 0-0.5mm.
  • refers to the absolute value of the difference between the actual length L'and the standard length of the knife L1;
  • refers to the actual diameter d'and The absolute value of the difference between the standard diameter dl of the knife.
  • the judgment of the tool is made more accurate, so that the distance between the presser foot 6 and the tool tip can be configured more accurately to ensure that the tool meets the range of the reference system, and the stable operation of the equipment is not prone to failure .
  • step S30 after automatically configuring the relative position of the presser foot 6 and the tool tip, it also includes: taking the standard length of the small knife L1 or the standard length L2 of the big knife as a reference, according to the actual length L'of the tool and the standard length of the small knife L1 or the standard length L2 of the big knife. Difference, automatically configure the height of the tool relative to the machine table. In practical applications, a tool measuring device is installed on the machine.
  • the spindle 4 After the system configures the distance between the presser foot and the tool tip, the spindle 4, the presser foot 6 and the tool 7 move along the Z axis until the tool tip reaches When the measuring position of the tool detector is detected and the tool position is detected by the laser in the tool detector, the position of the tip of the tool is measured to confirm Determine the distance between the tool and the plane of the machine table to prepare for drilling.
  • step S40 the PCB board is drilled, combined with the drilling equipment shown in FIG. 3, during processing, the spindle clamp 1 is lowered, and the presser foot 6 presses the workpiece, and then the spindle clamp 1 continues to descend and drives the spindle 4 to descend , Thereby driving the tool 7 down and drilling.
  • the spindle clamp 1 rises until the tool 7 and the presser foot 6 are separated from the PCB board. If there are holes to be processed by the tool 7 on the PCB board, the spindle clamp 1 will move to the corresponding position and continue drilling.
  • the system judges whether there are any holes to be machined, thereby judging whether the tool needs to be changed, if yes, repeat the above steps S10-S40, if not, the program ends, and the drilling is performed carry out.
  • Drilling equipment is a device that requires very high drilling efficiency and accuracy. Under normal circumstances, each spindle can process 8-10 holes or more per second, so the distance between the presser foot 6 and the tool tip is critical The index has very strict requirements. If the distance is too large, the distance between the tool tip and the workpiece will be large, and the Z-axis drilling action distance will increase, which greatly affects efficiency; if the distance is too small, the tool tip will easily scratch the cover of the workpiece or precede the presser foot 6 Press the workpiece tightly, which can easily cause accuracy deviation and even break the tool. Therefore, the distance from the tool tip to the presser foot 6 is usually set in the range of l-2mm and remains unchanged, which limits the tool length in related technologies to a uniform length. Conversely, if a small knife with a shorter length is used for processing under the structure of the related art, the distance between the presser foot 6 and the tool tip will be increased, thereby significantly reducing the efficiency of drilling processing.
  • FIG. 11 it is a schematic diagram of the drilling cycle of the PCB drilling method of this application, where t0-t6 is an entire drilling cycle, t0 -t3 is the Z-axis movement process of the drilling cycle, and the xy-axis stops.
  • the Z axis quickly moves downward from the initial position of the drilling to approach the board surface of the PCB board.
  • the presser foot approaches the board surface of the PCB board for a very small distance (this distance can be Setting), at this time the Z axis speed reaches the set drilling processing feed rate (the feed rate is one of the important process parameters of drilling, mainly determined by the tool diameter, spindle speed and plate characteristics), but usually this speed is very high slow.
  • tl' can be considered as the tip of the knife starts to contact the surface of the PCB board to start the formal cutting process. Therefore, the distance from the presser foot to the tool tip is included in the tl-tl' process. If the distance from the presser foot to the tool tip increases, the Z-axis speed at this time is very slow, so the time of tl' will be greatly increased.
  • tl-t2 is the cutting process, t2-t3 Z axis decelerates and returns. Return to the initial height when it reaches the t3 position.
  • t4-t5 is the synchronous movement of the xy axis, and the Z axis is stationary.
  • t3-t4 t5-t6 is the delay time.
  • the unit of time t is s
  • the unit of speed v is m/s.
  • the Z axis travels at a very slow feed rate through a displacement including the distance from the presser foot to the tool tip.
  • the distance will change due to the length of the knife It is very long, so the ti-tr of each hole becomes very long, which ultimately leads to a significant decrease in drilling efficiency.
  • it can be ensured that the displacement of the ti-tr segment when using a small knife is the same as that of a large knife, so the efficiency is not affected.
  • the presser foot 6 Before the tool tip touches the workpiece to be drilled, the presser foot 6 first touches the workpiece to be drilled, and flattens the workpiece to be drilled to ensure that the fine tool tip does not deflect, slide or even break when it contacts the workpiece to be drilled. , Especially for the tip of a knife;
  • the presser foot 6 is provided with an air duct for air intake, which can form a rotating air flow field and take away the dust together with the vacuum negative pressure to improve the reliability of dust collection; and the dust can be carried Heat dissipation reduces the temperature of the tool, which is helpful for fast, efficient and accurate drilling;
  • the tool After drilling, the tool is lifted away from the workpiece with the spindle.
  • the distance between the tool tip and the workpiece is generally required to be as small as possible; in order to ensure that the tool tip does not scratch the workpiece, the thin cover on the surface of the workpiece is not damaged
  • the vacuum negative pressure is brought up.
  • the presser foot 6 is required to block the cover of the workpiece surface. After the presser foot 6 leaves the workpiece, the x and y axes can move to the next drilling position for the next drilling, so as to ensure that every Stability and reliability during secondary drilling and changing drilling positions.

Landscapes

  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Manufacturing & Machinery (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Drilling And Boring (AREA)

Abstract

La présente invention concerne un procédé de perçage de carte de circuit imprimé et un appareil de perçage. Le procédé de perçage de carte de circuit imprimé comprend ce qui suit : S10, un outil (7) est saisi et modifié par un mécanisme de changement d'outil (S10) ; l'outil (7) est jugé comme une petite ou une grande lame (S20) ; les positions relatives d'un pied presseur (6) et d'une pointe d'outil sont automatiquement configurées avec la longueur standard (L1) de petites lames ou la longueur standard (L2) de grandes pales en tant que référence (S30) ; et le forage est effectué sur des sites de trous correspondants sur l'outil (7) (S40). Deux normes différentes sont établies pour de petites pales et de grandes pales respectivement ; une distance entre le pied presseur (6) et la pointe de l'outil est réglée en fonction de l'outil réellement saisi (7). Dans la position de départ du forage, la distance entre la pointe d'outil de tous les outils de forage (7) et le pied presseur est identique, assurant la compatibilité des outils (7) de différentes longueurs pendant le traitement, améliorant la précision de forage et réduisant le coût de forage.
PCT/CN2019/121608 2019-02-28 2019-11-28 Procédé de perçage de carte de circuit imprimé et appareil de perçage WO2020173158A1 (fr)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
CN201910151346 2019-02-28
CN201910151346.4 2019-02-28
CN201911076159.0 2019-11-06
CN201911076159.0A CN111629517B (zh) 2019-02-28 2019-11-06 一种pcb钻孔方法及钻孔设备

Publications (1)

Publication Number Publication Date
WO2020173158A1 true WO2020173158A1 (fr) 2020-09-03

Family

ID=72238811

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/CN2019/121608 WO2020173158A1 (fr) 2019-02-28 2019-11-28 Procédé de perçage de carte de circuit imprimé et appareil de perçage

Country Status (1)

Country Link
WO (1) WO2020173158A1 (fr)

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2001341052A (ja) * 2000-05-31 2001-12-11 Hitachi Via Mechanics Ltd ワークの加工方法および工具の折損検出方法並びに加工装置
CN1705423A (zh) * 2004-06-01 2005-12-07 日立比亚机械股份有限公司 印刷电路板钻孔方法及印刷电路板加工设备
US20110182688A1 (en) * 2010-01-25 2011-07-28 Schwartzman Everett H Tool release actuating mechanism for high speed rotating spindle
CN102728864A (zh) * 2011-03-31 2012-10-17 维嘉数控科技(苏州)有限公司 印刷电路板钻孔机快钻装置
CN105500086A (zh) * 2014-09-23 2016-04-20 维嘉数控科技(苏州)有限公司 钻孔机及其换刀方法
CN108748387A (zh) * 2018-07-24 2018-11-06 珠海市同辉电子有限公司 一种pcb钻孔设备

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2001341052A (ja) * 2000-05-31 2001-12-11 Hitachi Via Mechanics Ltd ワークの加工方法および工具の折損検出方法並びに加工装置
CN1705423A (zh) * 2004-06-01 2005-12-07 日立比亚机械股份有限公司 印刷电路板钻孔方法及印刷电路板加工设备
US20110182688A1 (en) * 2010-01-25 2011-07-28 Schwartzman Everett H Tool release actuating mechanism for high speed rotating spindle
CN102728864A (zh) * 2011-03-31 2012-10-17 维嘉数控科技(苏州)有限公司 印刷电路板钻孔机快钻装置
CN105500086A (zh) * 2014-09-23 2016-04-20 维嘉数控科技(苏州)有限公司 钻孔机及其换刀方法
CN108748387A (zh) * 2018-07-24 2018-11-06 珠海市同辉电子有限公司 一种pcb钻孔设备

Similar Documents

Publication Publication Date Title
TWI726624B (zh) 一種pcb鑽孔方法及鑽孔設備
CN101695767B (zh) 广角数控式单流表自动开孔设备
CN104708088A (zh) 一种自动压紧多孔精密钻铰夹具钻铰零件的方法及夹具
CN101306445A (zh) 成型装置
CN110395896B (zh) 光电玻璃切割机
WO2020173158A1 (fr) Procédé de perçage de carte de circuit imprimé et appareil de perçage
CN111376054A (zh) 一种带有扩孔功能的钻孔设备
CN217776416U (zh) 一种用于加工圆周孔的分度装置
KR20040104409A (ko) 구멍뚫기 가공방법
CN103586540B (zh) 一种电机换向器内孔加工装置
CN203599645U (zh) 一种电机换向器内孔加工装置
CN213646833U (zh) 一种加工高精度模具用数控雕铣自吸尘装置
CN112462686B (zh) 一种基于反转形貌法的刀具磨损测量位移控制压入装置
CN108274053B (zh) Vvt转子自动化加工工艺
CN211072600U (zh) 一种数控离管切割一体机
CN220128217U (zh) 一种扇形刀具孔钻孔装置
CN220547969U (zh) 一种数控车床自动化上料装置
CN217070990U (zh) 一种高精度半自动铰孔机
CN217370738U (zh) 一种加工联轴器十字槽设备
CN209857846U (zh) 一种孔位检具
CN204657956U (zh) 多品种重型缸体自动加工线
CN213701896U (zh) 一种精密高速机床
CN111889796B (zh) 一种板材双面拉槽加工方法
CN220407968U (zh) 一种数控机床用高精度辅助装置
CN210335171U (zh) 一种转子加工工装

Legal Events

Date Code Title Description
121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 19916845

Country of ref document: EP

Kind code of ref document: A1

NENP Non-entry into the national phase

Ref country code: DE

122 Ep: pct application non-entry in european phase

Ref document number: 19916845

Country of ref document: EP

Kind code of ref document: A1

122 Ep: pct application non-entry in european phase

Ref document number: 19916845

Country of ref document: EP

Kind code of ref document: A1

32PN Ep: public notification in the ep bulletin as address of the adressee cannot be established

Free format text: NOTING OF LOSS OF RIGHTS PURSUANT TO RULE 112(1) EPC (EPO FORM 1205A DATED 18.03.2022)

122 Ep: pct application non-entry in european phase

Ref document number: 19916845

Country of ref document: EP

Kind code of ref document: A1