Component placement device as well as a method for picking up a component and placing a component on a substrate

Abstract

A component placement device for picking up a component and placing a component on a substrate device comprises a holder which is movable at least in a main direction, as well as a nozzle for picking up a component. The nozzle is movable at least in a direction opposite the main direction relative to the holder. The component placement device comprises a fluid flow channel which opens or closes upon movement of the nozzle in the direction opposite the main direction relative to the holder, detection means for detecting the opening or closing of the fluid flow channel as well as means for controlling the movement of the holder in at least the main direction on the basis of a signal delivered by the detection means concerning the opening or closing of the fluid flow channel.

Claims

1. A component placement device for picking up a component and placing a component on a substrate, which component placement device comprises a holder which is movable at least in a main direction, as well as a nozzle for picking up a component, which nozzle is movable relative to the holder at least in a direction opposite the main direction, characterised in that the nozzle is provided with a passage connected to a vacuum source and to at least one opening of a component pick-up part, which nozzle is also provided with an opening in a wall of the nozzle located between the vacuum source and the at least one opening, which opening is in open communication with the passage, wherein the holder is provided with a channel which is in communication with the opening and the passage via a closable connection, wherein a fluid flow channel comprising at least part of the passage, the opening and the channel is being opened or closed by the nozzle at the closable connection upon movement of the nozzle relative to the holder in the direction opposite to the main direction, the component placement device further comprises detection means for detecting the opening or closing of the fluid flow channel as well as means for controlling the movement of the holder in at least the main direction on the basis of a signal delivered by the detection means concerning the opening or closing of the fluid flow channel.

2. The component placement device according to claim 1, characterised in that the fluid flow channel will open upon movement of the nozzle in the direction opposite the main direction relative to the holder.

3. The component placement device according to claim 2, characterised in that the passage extends through a component pickup part of the nozzle, wherein the fluid flow resistance of the passage in the component pickup part is greater than the joint fluid flow resistance of the opening in the wall of the nozzle and the channel in the holder.

4. The component placement device according to claim 1, characterised in that the passage extends through a component pickup part of the nozzle, wherein the fluid flow resistance of the passage in the component pickup part is greater than the joint fluid flow resistance of the opening in the wall of the nozzle and the channel in the holder.

5. The component placement device according to claim 1, characterised in that the nozzle is movable against spring force in the direction opposite the main direction relative to the holder.

6. The component placement device according to claim 1, characterised in that the nozzle is connected to the holder by means of two leaf springs.

7. A method for picking up a component and placing a component on a substrate using a component placement device according to claim 1, which component placement device comprises a holder which is movable at least in a main direction, as well as a nozzle for picking up a component, which nozzle is movable relative to the holder at least in a direction opposite the main direction, characterised in that the nozzle is provided with a passage connected to a vacuum source and to at least one opening of a component pick-up part, which nozzle is also provided with an opening in a wall of the nozzle located between the vacuum source and the at least one opening, which opening is in open communication with the passage, wherein the holder is provided with a channel which is in communication with the opening and the passage via a closable connection, wherein a fluid flow channel comprising at least part of the passage, the opening and the channel is being opened or closed by the nozzle at the closable connection upon movement of the nozzle relative to the holder in the direction opposite the main direction, wherein the holder is moved in the main direction, in the direction of the component upon picking up of the component or in the direction of the substrate upon placement of the component on the substrate, until the nozzle comes into contact with the component upon picking up the component or until the component comes into contact with the substrate upon placement of the component, after which, upon further movement of the holder in the main direction, the nozzle is moved relative to the holder in the direction opposite to the main direction, wherein the fluid flow channel of the component placement device is opened or closed, which opening or closing is detected by detection means, after which further movement of the holder in at least the main direction is controlled on the basis of a signal delivered by the detection means regarding the opening or closing of the fluid flow channel.

8. The method according to claim 7, characterised in that the further movement of the holder in the main direction is stopped on the basis of a signal delivered by the detection means regarding the opening or closing of the fluid flow channel.

9. The method according to claim 7, characterised in that the holder is moved a predetermined distance in the main direction on the basis of a signal delivered by the detection means regarding the opening or closing of the fluid flow channel.

10. The method according to claim 7, characterised in that the fluid flow channel is opened upon movement of the nozzle in the direction opposite the main direction relative to the holder.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention will now be explained in more detail with reference to the drawing, in which:

(2) FIGS. 1A and 1B are a cross-sectional view and a detail view, respectively, of a first embodiment of a component placement device according to the invention;

(3) FIG. 2 is a view of the component placement device of FIG. 1A while the component is being moved to a desired position on a substrate;

(4) FIG. 3 is a view of the component placement device of FIG. 1A during the placement of the component at a desired position on a substrate;

(5) FIG. 4 is a schematic diagram for controlling the movement of the holder of the component placement device shown in FIG. 1A;

(6) FIGS. 5A and 5B are views of a second embodiment of a component placement device according to the invention while the component is being moved to a desired position on a substrate and while the component is being placed at a desired position on a substrate, respectively;

(7) Like parts are indicated by the same numerals in the figures.

DESCRIPTION OF THE DRAWINGS

(8) FIGS. 1A and 1B show a cross-sectional view and a detail view, respectively, of a component placement device 1 according to the invention. The component placement device comprises a holder 2, which is movable at least in a main direction indicated by arrow P1, and also a nozzle 3 for picking up a component 4. The nozzle 3 is movable relative to the holder 2 at least in a direction opposite the main direction, as indicated by the arrow P2. The directions indicated by the arrows P1, P2 extend parallel to a central axis 5.

(9) The holder 2 has a cylindrical housing 6, which is closed at an upper side and a bottom side by an upper wall 7 and a lower wall 8, respectively. The holder 2 is provided with a pipe 9 in the upper wall 7 of the holder 2, which pipe 9 is connected to a vacuum source (not shown). The lower wall 8 is provided with an opening 9, through which the nozzle 3 extends. The cylindrical housing 6 accommodates a cylindrical element 10, through which the nozzle 3 extends. The cylindrical housing 6, the upper wall 7 and the cylindrical element 10 define a vacuum chamber 11. The cylindrical element 10 comprises a cylindrical chamber 12, which is in open communication with the environment via a number of channels 13 that extend transversely to the central axis 5 and through the cylindrical housing 6. Accordingly, normal ambient pressure prevails in the cylindrical chamber 12. A sealing ring 14 having an inner diameter D1 is provided in the cylindrical chamber 12, on a side near the lower wall 8. The inner diameter D1 is for example 5-10 mm, for example 7 mm.

(10) The nozzle 3 comprises a tube 15 extending along the central axis 5, which defines a passage 16. The tube 15 has an outer diameter D2. The outer diameter D2 is for example 3-8 mm, for example 5 mm. Provided in a wall of the tube 15 are a number of openings 17, which open into the cylindrical chamber 12. In the cylindrical chamber 12, the tube 15 is provided with an external flange 18.

(11) At the upper side, the passage 16 opens into the vacuum chamber 11. Near the upper side, the tube 15 is provided with an external flange 20. A biased spring 19 is provided between the flange 20 and the upper wall 7, which spring urges the nozzle 3 in the direction indicated by the arrow P1, causing the external flange 18 to be pressed against the sealing ring 14. The diameters D1 and D2 are preferably such that D2*D2 approximately equals D1*D1−D2*D2, so that the forces acting on the flange 18 and the nozzle 3 as a result of the partial vacuum and the ambient pressure substantially cancel out one another.

(12) Near the bottom side, the tube 15 is provided with a component pickup part 21, which is provided with one or more narrow passages 21′, which are connected to the passage 16 and which are in open communication with the environment. The component pickup part 21 has an outer diameter D3 on a side remote from the tube 15. The outer diameter D3 depends on the size of the component to be picked up; in practice it will often range between the 0.1 and 3 mm.

(13) The nozzle 3 is connected to an inner wall 23 of the cylindrical housing 6 of the holder 2 by means of two leaf springs 22. The leaf springs 22 are provided below the flange 20 in the vacuum chamber 11 and below the cylindrical element 10 near the lower wall 8.

(14) As shown in FIG. 1B, the leaf spring 22 comprises an outer ring 24, which is provided with three projections 25, which are connected to the inner wall 23 of the cylindrical housing 6 of the holder 2. The leaf spring 22 further comprises an inner ring 26, which is provided with three projections 27, which are connected to the outer wall 28 of the tube 15 of the nozzle 3. Located between the outer ring 24 and the inner ring 26 are a number of rings 29, which are connected to adjacent rings 24, 26, 29 via bridge segments 30. The pair of leaf springs 22 forms a good lineair guide for the nozzle 3 in relation to the holder 2.

(15) FIG. 2 shows the component placement device 1 while the component 4 is being moved, by driving means known per se (not shown), to a desired position on a substrate 31. As a result of the partial vacuum created in the passages 16, 21′ by means of the vacuum source via the vacuum line 9, a component 4 is held by the component pickup part 21. The component 4 has for example been picked up from a component supplying device that is known per se. While the component placement device 1 is being moved from the component supplying device near the desired position on the substrate 31, the nozzle 3 is pressed in the main direction indicated by the arrow P1 by the spring 19, causing the external flange 18 to be pressed against the sealing ring 14. The openings 17 open into a space 32 enclosed by the cylindrical element 10, the flange 18 and the sealing ring 14, so that the fluid connection between the passage 16 and the channels 13 is closed. Once the component 4 is present above the desired position on the substrate 31, the component placement device 1 will be moved in the main direction indicated by the arrow P1.

(16) At some point the component 4 will touch the substrate 31, as a result of which the component 4 and the nozzle will no longer be moved in the main direction indicated by the arrow P1. The holder 2, on the other hand, will move further against spring force in the main direction indicated by the arrow P1, so that the nozzle 3 will be moved in a direction opposite the main direction relative to the holder 2, as indicated by the arrow P2. See FIG. 3. The flange 18 is moved away from the sealing ring 14, so that simultaneously an open fluid connection through the channels 13, the chamber 12, the openings 17 and the passage 16 is formed. The channels 13, the chamber 12, the openings 17 and the passage 16 form the fluid flow channel. As a result of this open fluid connection in the fluid flow channel, flow of fluid to the vacuum source will be started through the pipe 9 in the direction indicated by the arrows P3. In this pipe 9 a sensor 33 (schematically indicated in FIG. 4) is provided, by means of which the pressure or flow of the fluid, such as air, can be detected both in the case of a closed fluid connection (FIG. 2) and in the case of an open fluid connection (FIG. 3). The joint fluid flow resistance of the passages 21′ in the component pickup part 21 is greater than the joint fluid flow resistance of the openings 17 in the nozzle 3 and the channels 13 in the holder 2, so that a change of the pressure or flow of the fluid can be detected relatively quickly.

(17) Subsequently, further movement of the holder 2 in the main direction indicated by the arrow P1 is controlled on the basis of the signal delivered by the sensor 33.

(18) The press-on force acting on the component 4 in FIG. 3 depends on the spring characteristic of the spring 19 and the relative movement of the nozzle 3 relative to the holder 2. The relative movement is in the order of 1 mm, for example 0.3 mm.

(19) FIG. 4 shows a schematic diagram of a control circuit 41 for controlling the movement of the holder 2 of the component placement device 1. The control circuit 41 comprises the sensor 33, a motor 42 for moving the holder 2 in the directions indicated by the arrows P1, P2, a position sensor 43 for determining the number of steps by which the holder 2 has been moved in the direction indicated by the arrows P1, P2, an AD converter ADC connected to the sensor 33 for converting the signal delivered by the sensor 33 into a digital signal, a microprocessor MC, a counter CNT connected to the position sensor 43 for determining the number of steps by which the holder 2 has been moved in the directions indicated by the arrows P1, P2. The control circuit 41 further comprises a unit 44 connected between the microprocessor MC and the motor 42 for driving the motor 42. The AD converter ADC converts the signal delivered by the sensor 33 and feeds it to the microprocessor MC. Furthermore, the signal from the position sensor 43 is fed to the microprocessor MC by the counter CNT. Based on the signal received from the AD converter ADC, the microprocessor MC determines whether the nozzle 3 is being moved in the direction indicated by the arrow P2 relative to the holder, and also the manner in which the holder 2 is subsequently to be moved. The movement of the holder 2 can be stopped, continued in the direction indicated by the arrow P1 or be continued in the direction indicated by the arrow P2. The microprocessor MC subsequently delivers a signal to the motor 42, via the unit 44, for moving the holder 2 in the desired manner. The control circuit 41 comprises the detection means for detecting the opening or closing of the fluid flow channel and the means for controlling the movement of the holder in at least the main direction.

(20) FIGS. 5A and 5B are views of a second embodiment of a component placement device 51 according to the invention while the component is being moved 4 to a desired position on a substrate 31 and while the component 4 is being placed at a desired position on a substrate 31, respectively. The component placement device 51 in large measure corresponds to the component placement device 1. The essential difference is that the nozzle 53 is provided with openings 57, which, in the extended position of the nozzle 53 relative to the holder 2 shown in FIG. 5A, are located near the upper side of the cylindrical chamber 12. The openings 57 are in open communication with the channels 13. The channels 13, the chamber 12, the openings 57 and the passage 16 form the fluid flow channel. As a result of this open fluid connection in the fluid flow channel, flow of fluid to the vacuum source will be started through the pipe 9 in the direction indicated by the arrows P5.

(21) Once the component 4 touches the substrate 31 upon placement of the component 4 on the substrate 31, the nozzle 53 will be moved in the direction indicated by the arrow P2 relative to the holder 2 against the spring force of the spring 19. At the same time, the openings 57 in the cylindrical element 10 will come to be located in the cylindrical element 10 and flow of fluid through the openings 57 will be reduced or be stopped altogether by the cylindrical wall 59 of the cylindrical element 10 opposite the openings 57. The fluid connection is now considered to be closed. A sensor is provided in the pipe 9, by means of which sensor the pressure or flow of the fluid, such as air, can be detected both in the case of an open fluid connection (FIG. 5A) and in the case of a closed fluid connection (FIG. 5B).

(22) In a similar manner as in the situation in which a component 4 is placed on a substrate 31, it is possible to determine the moment of contact between the nozzle 3, 53 and the component 4 upon picking up a component 4 from a component pickup position by moving the nozzle 3, 53 relative to the holder 2, the attendant opening or closing of a fluid connection and the detection of a change in the pressure or the flow of fluid.

(23) It is also possible to provide a precise lineair guidance other than through the use of leaf springs 22.

(24) Instead of being cylindrical in shape, the housing 6 and the element 10 may also have a rectangular or other shape.

(25) It is also possible that the joint fluid flow resistance of the passages 21′ in the component pickup part 21 is smaller than the joint fluid flow resistance of the openings 17 in the nozzle 3 and the channels 13 in the holder 2. The difference between the joint fluid flow resistance of the passages 21′ in the component pickup part 21 and the joint fluid flow resistance of the openings 17 in the nozzle 3 and the channels 13 in the holder 2 must be large enough, so that the pressure difference or the difference in fluid flow that occurs when a nozzle does not carry a component, when a component is being picked up and when the nozzle is moved in the holder makes it possible to distinguish the different situations from each other.

(26) It is also possible that the opening or closing of the fluid flow channel will not take place until the nozzle has been moved a predetermined distance relative to the holder.

(27) In the case of a relatively long movement of the nozzle relative to the holder it is also possible to successively open or close more channels, so that different changes in pressure of fluid flow will occur. These changes will be detected by the detection means, from which detection the movement of and/or the force on the nozzle can subsequently be derived.

LIST OF REFERENCE NUMERALS

(28) 1 component placement device 2 holder 3 nozzle 4 component 5 central axis 6 housing 7 upper wall 8 lower wall 9 pipe 10 element 11 vacuum chamber 12 chamber 13 channel 14 sealing ring 15 tube 16 passage 17 opening 18 flange 19 spring 20 flange 21 component pickup part 21′ passage 22 leaf spring 23 inner wall 24 outer ring 25 projection 26 inner ring 27 projection 28 outer wall 29 ring 30 bridge segment 31 substrate 32 space 33 sensor 41 control circuit 42 motor 43 position sensor 44 unit 51 component placement device 53 nozzle 57 opening 59 wall ADC AD converter CNT counter D1 inner diameter D2 inner diameter MC micro-processor P1 arrow P2 arrow P3 arrow P5 arrow