JP6120542B2 - Mounting head for surface mounting machine - Google Patents

Description

  The present invention relates to a mounting head for adsorbing and holding components and mounting the held components on a substrate in a surface mounter for mounting components such as IC chips on the substrate.

  The surface mounter picks up the component by suction from the component supply unit with a mounting head having a component holder such as a nozzle, holds the component as it is, transfers it to the substrate, and mounts it at a predetermined position on the substrate. It is configured.

  As such a mounting head, a plurality of spindles are mounted on the head main body so as to be rotatable in the T direction around the axis and movable in the Z direction along the axis, and a component such as a nozzle is held at the tip (lower end) of the spindle. What has the structure with which the tool was mounted | worn is known (for example, patent document 1). An air passage that leads to the component holder is formed inside the spindle. By supplying a negative pressure to the component holder through this air path, the component is adsorbed and held, and also through the air passage to the component holder. The component held by supplying positive pressure is mounted on the substrate. That is, in the mounting head, by switching between the negative pressure supply path that supplies negative pressure to the air passage inside the spindle and the positive pressure supply path that supplies positive pressure, the parts are adsorbed or mounted on the board. To do.

  A spool is known as a mechanism for switching the route. FIG. 4 is a conceptual diagram showing a conventional path switching mechanism using a spool. The spool 10 is supplied from a negative pressure input port 11 communicating with the negative pressure supply path, a positive pressure input port 12 communicating with the positive pressure supply path, and a negative pressure or positive pressure input port 12 supplied from the negative pressure input port 11. The path is switched by moving a rod-shaped spool body 14 having an output port 13 for outputting positive pressure and having a plurality of stages of O-rings 14a in the axial direction thereof. That is, when the spool body 14 is moved downward from the neutral position in FIG. 4A as shown in FIG. 4B, negative pressure is output from the output port 13, while upward as shown in FIG. 4C. When moved, a positive pressure is output from the output port 13.

  FIG. 5 conceptually shows a conventional example in which the above-described spool is applied to path switching between a negative pressure supply path and a positive pressure supply path in the mounting head. A spindle 30 is mounted on the head main body 20 of the mounting head so as to be rotatable in the T direction around the axis and movable in the Z direction along the axis. A nozzle 31 is mounted as a component holder at the tip of the spindle 30, and an air passage 32 communicating with the nozzle 31 is formed inside the spindle 30. The output port 13 of the spool 10 communicates with the inlet 32a of the air passage. Further, a negative pressure supply path 21 communicates with the negative pressure input port 11 of the spool 10, and a positive pressure supply path 22 communicates with the positive pressure input port 12. The path leading to the air passage 32 through the output port 13 by the path switching by the spool 10 described in FIG. 4 is referred to as a negative pressure supply path 21 or a positive pressure supply path 22. Thereby, a component is adsorbed by the nozzle 31, or the component is mounted on a substrate.

  Here, it is desirable that the air passage 32 formed inside the spindle 30 is as short as possible in order to improve the responsiveness of the component suction or mounting by the nozzle 31. In addition, dust and the like are likely to accumulate in the air passage 32, and it is necessary to clean the air passage 32 periodically or at any time. From this point, the air passage 32 is preferably short. In order to shorten the air passage 32, it is necessary to provide the inlet 32a of the air passage below the spindle 30 and to be close to the nozzle 31.

  On the other hand, in the conventional mounting head, the spool 10 is arranged vertically as shown in FIG. 5 due to restrictions on the arrangement space, and its output port 13 is connected to the negative pressure input port 11 and the positive pressure due to the configuration of the spool 10. It is arranged between the input port 12, that is, at an intermediate position in the height direction of the spool 10. Further, in the mounting head, a lower limit position where the spool 10 can be disposed is defined from the viewpoint of securing a movement margin in the Z direction of the spindle 30 (nozzle 31). Therefore, in the conventional mounting head, when the air passage inlet 32a is simply provided below the spindle 30 and brought closer to the nozzle 31, the configuration shown in FIG. 6 is obtained. However, in this configuration, a new air path 23 that leads from the output port 13 of the spool 10 to the inlet 32a of the air passage is required, and an extra plane space is required to provide the air path 23. As a result, the mounting head is increased in size.

JP 2010-157635 A

  The problem to be solved by the present invention is that in a mounting head of a surface mounter that uses a spool for switching between a negative pressure path and a positive pressure path, it is possible to increase the component adsorption or mounting responsiveness without causing an increase in the size of the mounting head. It is to be able to improve.

According to one aspect of the present invention, a spindle is mounted on the head body, a component holder is mounted on the tip of the spindle, and an air passage leading to the component holder is formed therein. The negative pressure is supplied to the component holder through the air passage to adsorb and hold the component by the component holder, and the positive pressure is supplied to the component holder through the air passage. In a mounting head of a surface mounting machine for mounting a substrate on a board, a spool for switching a path between a negative pressure supply path for supplying a negative pressure to the air path and a positive pressure supply path for supplying a positive pressure to the air path is provided on the spindle. There is provided a mounting head of a surface mounting machine, characterized in that the mounting head is disposed so as to cross obliquely with respect to the axis.

  According to the present invention, since the spool for switching the path between the negative pressure supply path and the positive pressure supply path is disposed so as to obliquely intersect the spindle axis, the air path leading to the component holder in the spindle is shortened. Therefore, even if the inlet of the air passage is provided below the spindle and close to the component holder, the air from the spool output port to the inlet of the spindle air passage is utilized by utilizing the space below the slanted spool. Since the path can be arranged, the mounting head is not increased in size. And since the air passage can be shortened, the responsiveness of component adsorption or mounting can be improved.

It is explanatory drawing which shows notionally one form of the mounting head of this invention. It is a conceptual diagram which shows the mechanism of the path | route switching by the spool in the mounting head of FIG. It is sectional drawing which shows one Example of the mounting head of this invention. It is a conceptual diagram which shows the mechanism of the path | route switching by the conventional general spool. FIG. 4 conceptually shows a conventional example in which the spool of FIG. 4 is applied to path switching between a negative pressure supply path and a positive pressure supply path in a mounting head. 6 shows a modification of the implementation head of FIG.

  FIG. 1 is an explanatory view conceptually showing one form of the mounting head of the present invention.

  A spindle 30 is mounted on the head main body 20 of the mounting head so as to be rotatable in the T direction around the axis and movable in the Z direction along the axis. A nozzle 31 is mounted as a component holder at the tip of the spindle 30, and an air passage 32 communicating with the nozzle 31 is formed inside the spindle 30.

  The spool 10 is disposed so as to cross obliquely with respect to the axis of the spindle 30. The spool 10 includes a negative pressure input port 11 that communicates with a negative pressure supply path 21 within the head body 20, a positive pressure input port 12 that communicates with a positive pressure supply path 22 within the head body 20, and an output port. In the spool described with reference to FIG. 4, there is one output port. However, in the form of FIG. 1, a negative pressure output port 13 a that outputs negative pressure from the negative pressure input port 11 and a positive pressure input port 12 are output ports. And a positive pressure output port 13b for outputting a positive pressure from the. Further, a positive pressure tank 15 is disposed between the positive pressure input port 12 and the positive pressure output port 13b. That is, the positive pressure from the positive pressure input port 12 is output from the tank output port 13c to the positive pressure tank 15, temporarily stored in the positive pressure tank 15, and the positive pressure is output from the positive pressure output port 13b.

  FIG. 2 is a conceptual diagram showing a path switching mechanism by the spool 10 described above. In FIG. 2, the negative pressure output port 13 a and the positive pressure output port 13 b of FIG. 1 are collectively shown as the output port 13. Further, a plurality of O-rings 14 a are mounted on the spool body 14 of the spool 10.

  FIG. 2A shows the first path switching in which the spool body 14 of the spool 10 is moved downward. In this first path switching, negative pressure from the negative pressure input port 11 is supplied to the output port 13, and negative pressure is output from the output port 13. At the same time, the positive pressure from the positive pressure input port 12 is supplied to the tank output port 13 c and the positive pressure is stored in the positive pressure tank 15. FIG. 2B shows the second path switching in which the spool body 14 of the spool 10 is moved upward. In the second path switching, the positive pressure from the tank output port 13c leading to the positive pressure tank is supplied to the output port 13, and the positive pressure is output from the output port 13. In this way, by switching between the first and second paths, the component is sucked by the nozzle, or the component is mounted on the board. The spool body 14 is driven by an actuator 40 shown in FIG.

  The path switching by the spool 10 will be described with reference to FIG. 1. In the first path switching, the negative pressure from the negative pressure input port 11 leading to the negative pressure supply path 21 is supplied to the negative pressure output port 13a. A negative pressure is output from 13a. The negative pressure is supplied to the air passage 32 in the spindle 30 through the air passage 23a. At the same time, the positive pressure from the positive pressure input port 12 communicating with the positive pressure supply path 22 is supplied to the tank output port 13 c and the positive pressure is stored in the positive pressure tank 15. On the other hand, in the second path switching, the positive pressure from the tank output port 13c leading to the positive pressure tank 15 is supplied to the positive pressure output port 13b, and the positive pressure is output from the positive pressure output port 13b. The positive pressure is supplied to the air passage 32 in the spindle 30 through the air passage 23b.

  As described above, in the mounting head of FIG. 1, the component is sucked by the nozzle 31 or the component is mounted on the substrate by the path switching by the spool 10. Since the spool 10 is arranged so as to obliquely intersect the axis of the spindle 30, an inlet 32a of the air passage is provided below the spindle 30 in order to shorten the air passage 32 leading to the nozzle 31 in the spindle 10. Even if it is close to 31, the space below the slanting inclined spool 10 can be used to arrange the air paths 23a, 23b leading from the spool output ports 13a, 13b to the spindle air passage inlet 32a. There is no increase in the size of the head. And since the air path 32 can be shortened, the responsiveness of component adsorption or mounting by the nozzle 31 can be improved.

  Note that the negative pressure output port 13a and the positive pressure output port 13b can be combined into one as the output port 13 as shown in FIG. That is, the negative pressure output port 13a and the positive pressure output port 13b in FIG. 1 are both output ports in the present invention.

  FIG. 3 is a cross-sectional view showing an embodiment of the mounting head of the present invention. 3, components corresponding to those in FIG. 1 are denoted by the same reference numerals as those in FIG. The mounting head shown in FIG. 3 is a rotary mounting head in which a plurality of spindles 30 are arranged along the circumferential direction of a columnar head body 20.

  In the configuration of FIG. 3 as well, path switching as described with reference to FIGS. 1 and 2 can be performed by appropriately arranging the O-rings mounted on the spool body 14 of the spool 10.

  That is, in the first path switching in which the spool body 14 of the spool 10 is moved downward, the negative pressure from the negative pressure input port 11 leading to the negative pressure supply path 21 is supplied to the negative pressure output port 13a, and the negative pressure output Negative pressure is output from the port 13a. The negative pressure is supplied to the air passage (not shown in FIG. 3) in the spindle through the air passage 23a. At the same time, the positive pressure from the positive pressure input port 12 communicating with the positive pressure supply path 22 is supplied to the tank output port 13c, and the positive pressure is stored in the positive pressure tank (not shown in FIG. 3). On the other hand, in the second path switching in which the spool body 14 of the spool 10 is moved upward, the positive pressure from the tank output port 13c leading to the positive pressure tank is supplied to the positive pressure output port 13b, and from the positive pressure output port 13b. Positive pressure is output. The positive pressure is supplied to the air passage of the spindle through the air passage 23b.

  Here, the upstream side of the positive pressure supply path 22 connected to the spool 10 passes through the center shaft 24 of the head body 20. Since the head main body 20 rotates in the R direction around the central axis 24, there is a necessary seal portion with sliding between members from the positive pressure supply path 22 in the central axis 24 to the spool 10. . Conventionally, such a seal required portion is sealed by Y packing, but in this embodiment, a seal required portion accompanied by sliding between members is sealed by a mechanical seal 25. In the mounting head, the positive pressure is used for breaking the vacuum after adsorbing the component with the negative pressure, so that the allowable value of the leak with respect to the original pressure is large. Therefore, there is no problem even if a mechanical seal is applied to the positive pressure supply path 22. Rather, the sliding resistance can be reduced and its fluctuation can be reduced as compared with the conventional Y packing seal. In addition, since the mechanical seal does not like mixing of dust or the like, the filter 26 is provided in the positive pressure supply path 22 in this embodiment.

DESCRIPTION OF SYMBOLS 10 Spool 11 Negative pressure input port 12 Positive pressure input port 13 Output port 13a Negative pressure output port 13b Positive pressure output port 14 Spool main body 14a O-ring 15 Positive pressure tank 20 Head main body 21 Negative pressure supply path 22 Positive pressure supply path 23, 23a, 23b Air path 24 Central shaft 25 Mechanical seal 26 Filter 30 Spindle 31 Nozzle (component holder)
32 Air passage 32a Air passage entrance 40 Actuator

Claims (3)

A spindle is mounted on the head body, and a component holder is mounted on the tip of the spindle, and an air passage leading to the component holder is formed therein, and the component holder is formed through the air passage. A surface mounting machine that adsorbs and holds a component by the component holder by supplying negative pressure to the component, and mounts the held component on a substrate by supplying positive pressure to the component holder through the air passage. In the mounting head,
A path switching spool between a negative pressure supply path for supplying negative pressure to the air passage and a positive pressure supply path for supplying positive pressure to the air passage is disposed so as to obliquely intersect the axis of the spindle. A mounting head for a surface mounting machine.   The spool has a negative pressure input port that communicates with the negative pressure supply path, a positive pressure input port that communicates with the positive pressure supply path, and a negative pressure that is supplied from the negative pressure input port by path switching. Or an output port for outputting a positive pressure supplied from the positive pressure input port, a positive pressure tank is disposed between the positive pressure input port and the output port, and the first path switching by the spool The negative pressure is supplied from the negative pressure input port to the output port, the positive pressure is supplied from the positive pressure input port to the positive pressure tank, and the positive pressure is supplied from the positive pressure tank by the second path switching by the spool. The mounting head of the surface mounter according to claim 1, wherein the output port is supplied to the output port.   The mounting head of the surface mounting machine according to claim 1, wherein a portion where the seal is required along with sliding between members is sealed by a mechanical seal in the positive pressure supply path in the head body.

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