KR0176617B1 - Nozzle changing method of mounting apparatus for electronic parts - Google Patents

Abstract

The nozzle replacement method of an electronic component mounting machine is disclosed. The disclosed nozzle replacement method includes a step of sensing by a sensor whether the nozzle replacement has been normally performed and lifting and lowering the stocker in which the nozzle is stored, thereby making it possible to speed up an operation in an abnormal operation and further reduce the replacement time. There is an advantage that can be shortened.

Description

Nozzle replacement method of electronic component mounter

The present invention relates to a nozzle replacement method of an electronic component mounting machine.

In general, as shown in FIG. 1, the electronic component mounting machine includes a head 1 horizontally moved by an XY axis mobile robot 2 and 3, and a nozzle holder 4 mounted on the head 1 to be elevated. ), A suction nozzle (not shown) is mounted at the tip of the nozzle holder 4, and the electronic component is detached and mounted on the substrate 5 by the nozzle.

Such a nozzle is exchanged and used according to the kind of electronic component to be attached or detached. Therefore, the mounting apparatus is equipped with the nozzle storage stocker 8 which accommodated various nozzles, and the system which selects and replaces a desired nozzle from the nozzle storage stocker 8 is provided.

In exchanging the nozzles, the exchanging operation was performed in the following order.

First, when the type of the component to be mounted is changed while the mounting and mounting operation of the component is performed with the nozzle currently in operation, the head 1 is moved to the upper part of the nozzle storage stocker 8 by the XY axis mobile robot 2, 3. Move.

At this time, the nozzle cover (8a, 8b) covering the upper surface of the nozzle storage stocker (8) is opened while the circular motion.

Then, after the head 1 is stopped at a desired position, ie, vertically above the empty space of the nozzle storage stocker 8, the nozzle holder 4 is lowered to separate the nozzle in operation.

When the lowering of the nozzle holder 4 is completed, the nozzle covers 8a and 8b are closed, and the nozzle holder 4 is raised again. At this time, the nozzles attached to the nozzle holder 4 are separated from the nozzle holder 4 by the closed nozzle covers 8a and 8b and remain in the nozzle storage stocker 8.

Subsequently, the head 1 is moved by the XY axis moving robots 2 and 3 above the desired replacement nozzle, and at the same time, the nozzle covers 8a and 8b are opened again.

Thereafter, the nozzle holder 4 is lowered to hold the nozzle and then to rise, and the nozzle covers 8a and 8b are closed after the nozzle holder 4 is raised.

As a result, the replacement operation of the nozzle is completed.

By the way, according to such a conventional nozzle replacement method, it is not immediately known whether the nozzle replacement operation was completed normally. This is only to be understood by the operator after confirming that no adsorption is performed in the parts adsorption operation subsequent to the nozzle replacement operation. Therefore, there is a problem that the delay of the action for the nozzle replacement operation error occurs to reduce the efficiency of the operation.

In addition, since the nozzle storage stocker 8 is fixed at a predetermined position, the lifting distance of the nozzle holder 4 is increased, and there is also a problem that the time required for replacement is long.

Therefore, the present invention was created to solve the above problems, it is possible to immediately recognize whether the normal replacement operation was performed during the nozzle replacement operation, and at the same time the nozzle of the electronic component mounting machine that can shorten the time required for the replacement operation The purpose is to provide an exchange method.

1 is a schematic perspective view of a conventional electronic component mounter,

2A and 2B show the main parts of the electronic component mounting machine according to the present invention.

2a is a cross-sectional view,

2b is a plan view,

3A to 3H are schematic diagrams showing step by step nozzle operation in accordance with the present invention;

4 is a flow chart of a nozzle exchange operation in accordance with the present invention.

Explanation of symbols for the main parts of the drawings

10 head 12 nozzle holder

11 ... working nozzle 11 '... storage nozzle

13 ... encoder 14 ... motor

20 Nozzle storage stocker 21,22 Optical fiber sensor

23, 24 ... Guide member 25 ... Nozzle cover

30.Drive cylinder

The present invention for achieving the above object is a nozzle replacement of an electronic component mounter for replacing a work nozzle supported by a nozzle holder provided on a mounter head to suck and remove a component with a storage nozzle housed in a nozzle storage stocker. A method, comprising: a first step in which a mounting head having a working nozzle mounted thereon moves to a position immediately above an empty space of the nozzle storage stocker; A second step of opening the nozzle cover on the top of the nozzle storage stocker while the nozzle storage stocker is raised, and lowering the nozzle holder; A third step of detecting that the work nozzle starts to pass through a predetermined sensing line by a sensor installed at an upper end of the nozzle storage stocker while the nozzle holder is descending, and calculating the nozzle holder height at that time; A fourth step of closing the nozzle cover; A fifth step of separating the work nozzle while interfering with the nozzle cover while the nozzle holder is raised; A sixth step of detecting that the nozzle holder has completely passed the sensing line by the sensor and calculating a nozzle holder height at that time; A seventh step of comparing the positions of the nozzle holders detected in the third step and the sixth step and generating an error message when the difference value is different from the length of the work nozzle by more than a predetermined deviation range; Compare the heights of the nozzle holders sensed in the third and sixth steps and when the difference value is within the predetermined deviation range with the length of the work nozzle, move the mounter head to the position immediately above the nozzle to be replaced. An eighth step to make; A ninth step of lowering the nozzle holder; A tenth step of detecting by the sensor that the nozzle holder has started to pass through the sensing line and calculating a nozzle holder height at that time; An eleventh step of attaching the storage nozzle stored in the nozzle storage stocker to the nozzle holder by lowering the nozzle holder; A twelfth step of opening the nozzle cover; A thirteenth step of raising the nozzle holder; A fourteenth step of detecting that the storage nozzle attached to the nozzle holder completely passes the detection line and calculating a nozzle holder height at that time; A fifteenth step of comparing the nozzle holder positions detected in the tenth step and the fourteenth step and generating an error message when the difference value is different from the length of the storage nozzle by a predetermined deviation range; When the nozzle holder position detected in the tenth step and the fourteenth step is compared and the difference value is within a predetermined deviation range from the length of the storage nozzle, the nozzle cover is closed and the nozzle storage stocker is lowered. And a sixteenth step.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2A and 2B schematically illustrate the structure of a head and nozzle storage stocker required to perform a nozzle change operation in accordance with the present invention.

Referring to the drawings, a head 10 is liftably connected to a motor 14 to which an encoder 13 is attached, and a nozzle holder 12 supporting the nozzle 11 is provided in the head 10. It is installed.

In addition, the nozzle storage stocker 20 for storing the plurality of waiting nozzles 11 ′ is provided to be capable of lifting up and down along the guide members 23 and 24 by the driving cylinder 30.

And the upper end of the nozzle storage stocker 20 is provided with a sensor for detecting the passage of the object, for example, optical fiber sensors 21, 22.

In addition, as shown in FIG. 2B, the nozzle cover 25 is installed to be opened and closed at an upper portion of the nozzle storage stocker 20. When the nozzle cover 25 is opened, the nozzles stored in the stocker 20 ( 11 ') may come out, but in a closed state as shown in the drawing, one side of the nozzle 11' may not interfere with the nozzle cover 25.

In such a structure, the nozzle replacement method according to the present invention is performed by the procedure shown in Figs. 3A to 3H are schematic views sequentially illustrating the nozzle replacement step according to the present invention, and FIG. 4 is shown in a flow chart.

First, referring to FIG. 3A, the mounting head 10 mounted with the work nozzle 11 moves to a position immediately above the empty space of the nozzle storage stocker 20 (FIG. 4; S1).

Subsequently, the nozzle storage stocker 20 is raised, and the nozzle cover (Fig. 2; 25) provided on the top of the nozzle storage stocker 20 so as to be openable and open (Fig. 4; S2) is opened.

Thereafter, as shown in FIG. 3B, the nozzle holder 12 is lowered (FIG. 4; S3), and at this time, the work nozzle (FIG. 2; 21, 22) is installed at the top of the nozzle storage stocker 20. It is detected that 11) has started to pass through the predetermined sensing line, and the height of the nozzle holder 12 at that time is calculated (FIG. 4; S4). At this time, the sensing line is a horizontal line formed by the sensors 21 and 22.

Next, it is determined whether the lowering of the nozzle holder 12 is completed, and the nozzle holder 12 is lowered until it is completed (FIG. 4; S5).

When the lowering of the nozzle holder 12 is completed, as shown in FIG. 3C, the nozzle cover 25 is closed (FIG. 4; S6), and then the nozzle holder 12 is raised (FIG. 4; S7). At this time, as shown in Figure 3d, the work nozzle 11 is separated from the interference to the nozzle cover (25).

When the nozzle holder 12 is raised, the sensor (FIGS. 2; 21 and 22) detects that the nozzle holder 12 completely passes the sensing line and calculates the nozzle holder height at that time (FIG. 4). ; S8).

Then, it is determined whether the raising of the nozzle holder is completed (FIG. 4; S9), and then, the heights of the nozzle holders calculated in the previous steps S4 and S8 are compared, respectively, and the difference between the length of the nozzle and the work nozzle 11 is determined. An error message is generated when it is different from the predetermined deviation range, and passes to the next step when it is within the deviation range (Fig. 4; S10).

After separating the work nozzle 11 by the above-described steps, as shown in FIG. 3E, the mounter head 10 moves to a position immediately above the storage nozzle 11 'to be replaced (FIG. 4; S11).

Subsequently, the nozzle holder 12 is lowered (FIG. 4; S12), and at this time, the nozzle holder 12 is attached to the sensing line by a sensor (FIG. 2; 21, 22) installed on the top of the nozzle storage stocker 20. It senses that it has started to pass through and calculates the height of the nozzle holder 12 at that time (FIG. 4; S13).

Then, it is determined whether the lowering of the nozzle holder 12 is completed, and the nozzle holder 12 is lowered until it is completed (FIG. 4; S14).

At this time, as shown in FIG. 3F, the storage nozzle 11 ′ in the nozzle storage stocker 20 is elastically attached to the nozzle holder by the lowering of the nozzle holder 12.

Thereafter, as shown in FIG. 3G, the nozzle cover 25 is opened (FIG. 4; S15), and the nozzle holder 12 is raised (FIG. 4; S16). At this time, the sensor 25 detects the completion of the sensing line passage of the storage nozzle 11 'and calculates the height of the nozzle holder 12 at that time (FIG. 4; S17).

Subsequently, after determining whether the raising of the nozzle holder 12 is completed (FIG. 4; S18), the heights of the nozzle holders 12 calculated in the previous steps S13 and S17 are compared, respectively, and the difference is different from the storage nozzle 11. An error message is generated when the length of the ')' differs from the predetermined deviation range, and passes to the next step when the deviation is within the deviation range (Fig. 4; S19).

Thereafter, as shown in FIG. 3H, the nozzle storage stocker 20 descends while the nozzle cover 25 is closed, thereby ending the nozzle replacement operation (FIG. 4; S20).

Therefore, according to the nozzle replacement method of the electronic component mounting machine as described above, the operator can immediately confirm whether the nozzle replacement is normally performed, thereby avoiding a decrease in the work efficiency due to work delay and the like. Lifting and lowering shortens the head moving distance at the time of nozzle replacement, and as a result, the replacement time is shortened.

Claims (1)

In the nozzle replacement method of the electronic component mounter which replaces the work nozzle which is supported by the nozzle holder installed so that the mounting head can be lifted up and down, and replaces a component with the storage nozzle stored in the nozzle storage stocker, A first step in which the mounting head to which the work nozzle is mounted moves to a position immediately above the empty space of the nozzle storage stocker; A second step of opening the nozzle cover on the top of the nozzle storage stocker while the nozzle storage stocker is raised, and lowering the nozzle holder; A third step of detecting that the work nozzle starts to pass through a predetermined sensing line by a sensor installed at an upper end of the nozzle storage stocker while the nozzle holder is descending, and calculating the nozzle holder height at that time; A fourth step of closing the nozzle cover; A fifth step of separating the work nozzle while interfering with the nozzle cover while the nozzle holder is raised; A sixth step of detecting that the nozzle holder has completely passed the sensing line by the sensor and calculating a nozzle holder height at that time; A seventh step of comparing the positions of the nozzle holders detected in the third step and the sixth step and generating an error message when the difference value is different from the length of the work nozzle by more than a predetermined deviation range; Compare the heights of the nozzle holders sensed in the third and sixth steps and when the difference value is within the predetermined deviation range with the length of the work nozzle, move the mounter head to the position immediately above the nozzle to be replaced. An eighth step to make; A ninth step of lowering the nozzle holder; A tenth step of detecting by the sensor that the nozzle holder has started to pass through the sensing line and calculating a nozzle holder height at that time; An eleventh step of attaching the storage nozzle stored in the nozzle storage stocker to the nozzle holder by lowering the nozzle holder; A twelfth step of opening the nozzle cover; A thirteenth step of raising the nozzle holder; A fourteenth step of detecting that the storage nozzle attached to the nozzle holder completely passes the detection line and calculating a nozzle holder height at that time; A fifteenth step of comparing the nozzle holder positions detected in the tenth step and the fourteenth step and generating an error message when the difference value is different from the length of the storage nozzle by a predetermined deviation range; When the nozzle holder position detected in the tenth step and the fourteenth step is compared and the difference value is within a predetermined deviation range from the length of the storage nozzle, the nozzle cover is closed and the nozzle storage stocker is lowered. The nozzle replacement method of the electronic component mounting machine comprising a;