(1) Field of the Invention
The present invention relates to a tape feeder.
(2) Description of the Related Art
A component mounting machine is conventionally provided as a machine that mounts an electronic component (hereinafter simply referred to as “component”) onto a substrate. In the component mounting machine, a mounting head takes out a component from a tape feeder by an absorbing nozzle and transfers and mounts it onto the substrate. The tape feeder feeds a carrier tape having a plurality of rectangular component storage units (cavities) which store components and which are provided at predetermined intervals in a feed direction, and conveys the component to a component take-out region where component take-out is performed. Provided as technologies related to the tape feeder are, for example, those described in Japanese Unexamined Patent Application Publication No. 2000-228600 (hereinafter referred to as Patent Reference 1) and Japanese Unexamined Patent Application Publication No. 2009-212194 (hereinafter referred to as Patent Reference 2).
In tape feeders of Patent References 1 and 2, a magnet is provided below an entire bottom surface of a component storage unit fed to a component take-out region. This suppresses, for example, standing of the component at the component storage unit.
However, a component storage position differs among the component storage units even in the same tape carrier. Therefore, in the component take-out by the mounting head, positional dislocation (absorption dislocation) from a predetermined component absorption position occurs, which consequently deteriorates positional accuracy of the component mounting. For example, carrier tapes of different vendors have different gap sizes at the component storage unit (a sum of gaps in the same direction on a plane between a side surface of the component storage unit and the component in a predetermined direction), but as shown in
A small-sized component inevitably has a large gap size at the component storage unit. Moreover, upon take-out of the small-sized component, the absorption dislocation has a great influence, resulting in failure to take out the component even if the absorption dislocation is small, so that the absorption error is likely to occur. Therefore, for the mounting of the small-sized component, it is strongly desired in particular to reduce the absorption dislocation.
In view of such a problem, it is an object of the invention to provide a tape feeder capable of reducing absorption dislocation and a carrier tape feeding method using the tape feeder.
To achieve the object described above, a tape feeder according to one aspect of the invention feeds a carrier tape including a plurality of component storage units of a rectangular shape provided at predetermined intervals in a feed direction, and includes a first magnetic force region which is provided below a bottom surface of the component storage unit fed to a feed region so as to extend in the feed direction below one side of the bottom surface in a width direction and which attracts a component of the component storage unit fed to the feed region to one side in the width direction.
Consequently, the component of the component storage unit in the feed region is attracted by the first magnetic force region to one side end of the component storage unit. As a result, all the components of the component storage units are attracted to one side ends of the component storage units for alignment in the feed region, which therefore reduce absorption dislocation.
Here, the tape feeder may include a second magnetic force region which is provided at back in the feed direction with respect to the first magnetic force region below the bottom surface of the component storage unit fed to the feed region and which attracts the component of the component storage unit fed to the feed region towards the back in the feed direction. Further, the first magnetic force region may be formed of a first magnet, the second magnetic force region may be formed of a second magnet, and the first magnet and the second magnet may be integrated together to form an L-shaped magnet.
Consequently, the component of the component storage unit moving in the feed direction in the feed region is attracted by the second magnetic force region to a rear end of the component storage unit in the feed direction by use of a force of feeding a tape. As a result, all the components of the component storage units are attracted to corners of the component storage units for alignment in the feed region, which can therefore further reduce the absorption dislocation.
Moreover, the first magnet may be provided below half of the bottom surface.
This consequently can suppress component standing and failure to perform component absorption by an absorbing nozzle due to a too strong force of attracting the component of the component storage unit by the first magnet.
Moreover, the first magnet may be formed of an elastic body.
This consequently permits a force received by the component and the carrier tape from the absorbing nozzle upon component take-out to be absorbed even when there is a change in a thickness of the carrier tape.
Moreover, the tape feeder may further include an elastic member of a plate-like shape supporting the bottom surface of the component storage unit fed to the feed region, wherein the first magnet may be attached to a surface of the elastic member opposite to a side on which the bottom surface is placed.
This consequently permits easy fitting of the first magnet and reduction of the absorption dislocation with simple configuration. Moreover, a magnetic force is inversely proportional to a square of a distance, but a distance between the first magnet and the carrier tape can be kept constant, thus permitting control of the force of attracting the component by the first magnet.
Moreover, the first magnet may be provided below bottom surfaces of the plurality of the component storage units fed to the feed region.
This consequently attracts all the components of the component storage units in the feed region to one side ends of the component storage units for alignment with high probability, which can therefore further reduce the absorption dislocation.
Moreover, a front end part of the first magnet in the feed direction may be provided below a portion occupying one fourth of an area of the bottom surface.
This consequently suppresses failure to perform the component absorption by the absorbing nozzle due to a too strong force of attracting the component of the component storage unit at the component take-out position by the first magnet.
Moreover, a carrier tape feeding method is a method of feeding in a tape feeder a carrier tape including a plurality of component storage units of a rectangular shape provided at predetermined intervals in a feed direction, and attracts a component of the component storage unit fed to a feed region in the tape feeder to one side of a bottom surface of the component storage unit in a width direction and towards back in the feed direction.
This consequently can reduce the absorption dislocation.
According to the invention, the absorption dislocation can be reduced, and thus cavity variation can be absorbed and the component take-out positions can be aligned to stabilize a component absorption rate and mounting accuracy.
The disclosure of Japanese Patent Application No. 2010-009476 filed on Jan. 19, 2010 including specification, drawings and claims is incorporated herein by reference in its entirety.
The disclosure of PCT application No. PCT/JP2011/000253 filed on Jan. 19, 2011, including specification, drawings and claims is incorporated herein by reference in its entirety.
These and other objects, advantages and features of the invention will become apparent from the following description thereof taken in conjunction with the accompanying drawings that illustrate a specific embodiment of the invention. In the Drawings:
Hereinafter, a tape feeder and a carrier tape feeding method using the tape feeder according to an embodiment of the present invention will be described, with reference to the accompanying drawings.
This component mounting machine includes: a base 100, a conveyance path 101, a component supply unit 103, a mounting head 105, a recognition camera 106, an XY robot 107, a waste tray 108, and a nozzle station 109.
The conveyance path 101 is disposed at a central part of the base 100, and conveys a substrate 104 to position it.
The component supply unit 103 has a plurality of tape feeders 102 arranged in parallel to each other, and supplies a plurality of kinds of components.
The mounting head 105 takes out the component from the component supply unit 103 and transfers and mounts it onto the substrate 104.
The recognition camera 106 recognizes the component absorbed to an absorbing nozzle of the mounting head 105 from the bottom of the component.
The XY robot 107 moves the mounting head 105 in an XY direction.
To the waste tray 108, the component is wasted.
The nozzle station 109 holds the absorbing nozzle of the mounting head 105.
The tape feeder 102 includes: a main body frame 120, a reel side plate 121, a supply reel 122, a feed roller 123, a ratchet 124, a feed lever 126, a tension spring 126a, a take-up reel 129, and a pressing cover 130.
The supply reel 122 is rotatably fitted to the reel side plate 121 coupled to the main body frame 120, and is wound with a carrier tape 122a holding the components.
The feed roller 123 pitch-feeds the carrier tape 122a pulled out from the supply reel 122.
The ratchet 124 rotates the feed roller 123.
The feed lever 126 rotates the ratchet 124 through fixed degrees by a link 125.
The take-up reel 129 takes up a cover tape 122b detached from the carrier tape 122a.
In the tape feeder 102 having the structure described above, the feed lever 126 is moved in an Y1 direction by a motor, an air cylinder, or the like to thereby rotate the ratchet 124 through the fixed degrees. Then in conjunction with the ratchet 124, the feed roller 123 rotates by a roller pitch. This feeds the carrier tape 122a by a component pitch defined as a space between the two adjacent components (component storage units). Then a force of pressing-out to the feed lever 126 is released, and the feed lever 126 returns in an Y2 direction, that is, to its original position by a bias force of the tension spring 126a. Repeating such a series of operations discharges the used carrier tape 122a to outside of the tape feeder 102. Note that the feed roller 123 may be rotated for the tape-feed of the carrier tape 122a by the motor without the aid of the feed lever 126, and that the take-up reel 129 may be wound by a motor different from the motor for rotating the feed roller 123. For example, in a case where the roller pitch is 2 mm and the component pitch is 2 mm, to feed the carrier tape 122a by the component pitch, the feed lever 126 is moved once. Note that the component pitch and the roller pitch do not have to be equal to each other.
The carrier tape 122a includes: a base material tape 122c and the cover tape 122b. The carrier tape 122a is supplied to the user in a taped state in which the carrier tape 122a is wound around the supply reel 122 a predetermined number of times.
The base material tape 122c includes a plurality of rectangular component storage units (concave parts) 141 which are provided in a feed direction of the carrier tape 122a successively at predetermined intervals and which store components 140 of one chip type.
The cover tape 122b is attached to a top surface of the base material tape 122c so as to cover openings of the component storage units 141, thereby packing the components 140.
The pressing cover 130 has a shutter 127 and a slit 128, and is fitted to the main body frame 120 in a manner such that the shutter 127 is located above the ratchet 124.
Upon take-out of the component 140, the shutter 127 opens to expose, from the top, the component 140 of the component storage unit 141 below the shutter 127. The absorbing nozzle of the mounting head 105 absorbs the exposed component 140 to take it out.
The slit 128 functions as a cover tape detaching unit, and detaches the cover tape 122b from the carrier tape 122a in front of the shutter 127.
The tape feeder 102 includes below the pressing cover 130 a plate spring 160 as an elastic member as shown in a perspective view of
To a bottom surface opposite to the top surface of the plate spring 160 where the tape feeder 102 thereabove is placed, a magnet 150 of an L-shaped, plate-like form as shown in a perspective view of
The first magnet 151 and the second magnet 152 are formed of an elastic body for the purpose of absorbing the force received by the component 140 and the carrier tape 122a from the absorbing nozzle upon the take-out of the component 140 by the absorbing nozzle.
Here, the magnet 150 is, for example, an isotropic Ba ferrite magnet, and a length of the first magnet 151 (a in
Hereinafter, a region provided with the pressing cover 130 for taking out the component 140 located therebelow, specifically, a region above the plate spring 160, and more specifically, a region including the component storage unit 141 below the shutter 127 and, for example, the three preceding component storage units 141 (in front of the component storage unit 141 below the shutter 127 in the feed direction) is defined as a component take-out region that is a feed region of the tape feeder 102.
The first magnet 151 is provided below the bottom surfaces of the component storage units 141 fed to the feed region so as to extend in the feed direction below one side of the bottom surfaces of the component storage units 141 in the width direction, and attracts the components 140 of the component storage units 141 fed to the feed region to one side in the width direction and towards bottom.
Here, the first magnet 151 is provided below only half the bottom surfaces of the component storage units 141 in the feed region in parallel to the feed direction so as to cover only half of areas of the bottom surfaces of the component storage units 141. Moreover, the first magnet 151 is located below the bottom surfaces of the three component storage units 141 including the component storage unit 141 at a component take-out position. Further, a front end part of the first magnet 151 in the feed direction is provided below a portion occupying one-fourth of the area of the bottom surface of the component storage unit 141 in the feed region. This prevents failure to absorb the component 140 by the absorbing nozzle upon the take-out of the component 140 due to a too strong force of attracting the component 140 at the component take-out position by the first magnet 151.
Moreover, since the first magnet 151 attracts the components 140 of the component storage units 141 in the feed region to one side in the width direction and towards the bottom, great magnetic flux density of the first magnet 151 results in standing of the components 140 at the component storage units 141. Especially in a case where the component 140 is a tiny component and a case where the component 140 is of a dice-like shape, such standing of the component 140 is likely to occur. Therefore, it is preferable that the one having a surface maximum magnetic flux density of 50 mT or below, for example, approximately 40 mT be used as the first magnet 151.
The second magnet 152 is provided at the back in the feed direction with respect to the first magnet 151 below the bottom surfaces of the component storage units 141 in the feed region, and attracts the components 140 of the component storage units 141 fed to the feed region to the back in the feed direction and towards the bottom.
Here, the second magnet 152 is so provided as to be separated from the component storage unit 141 at the component take-out position by a distance sandwiching the two component storage units 141. Therefore, this prevents the standing of the component 140 at the component take-out position and failure to absorb the component 140 by the absorbing nozzle upon the take-out of the component 140 due to a too strong force of attracting the component 140 by the second magnet 152.
Since the second magnet 152 attracts the components 140 of the component storage units 141 towards the feed direction and towards the bottom in the feed region, great magnetic flux density of the second magnet 152 results in standing of the components 140 at the component storage units 141. Therefore, it is preferable that the one having a maximum surface magnetic flux density of 50 mT or below, for example, approximately 40 mT be used.
Plan views of
First, as shown in
Next, as shown in
Next, as shown in
Finally, as shown in
Making comparison between
As described above, the tape feeder 102 of this embodiment includes the first magnet 151 below one side of the bottom surfaces of the component storage units 141 in the feed region, and includes the second magnet 152 of an island shape at the back in the feed direction with respect to the first magnet 151. Therefore, the components 140 of the component storage units 141 in the feed region are attracted by the first magnet 151 to side ends of the component storage units 141 in the width direction and simultaneously attracted by the second magnet 152 to rear ends of the component storage units 141 in the feed direction by use of a force of feeding the carrier tape 122a. As a result, all the components 140 of the component storage units 141 are pulled to the ends of the component storage units 141 for alignment, which can therefore reduce the absorption dislocation.
Moreover, with the tape feeder 102 of this embodiment, the first magnet 151 and the second magnet 152 are provided below the bottom surfaces of the component storage units 141 in the feed region. Therefore, the components 140 of the component storage units 141 in the feed region are attracted towards the bottom of the component storage units 141 by the first magnet 151 and the second magnet 152. This consequently prevents the components 140 of the component storage units 141 to pop out of the component storage units 141 and stand in the feed region.
Moreover, with the tape feeder 102 of this embodiment, the first magnet 151 is provided below half of the bottom surfaces of the component storage units 141. This consequently can prevent the components 140 of the component storage units 141 from being forcefully attracted to stand by the first magnet 151.
Hereinafter, a magnet 150 according to Comparative Example 1 of this embodiment will be described.
The magnet 150 according to this comparative example is different from the magnet 150 of
A plan view and a sectional view of
The components 140 fed to the feed region are also attracted towards the feed direction and the width direction in the feed region by the magnet 150 according to this comparative example, and thereby move to the ends of the component storage units 141 in the feed direction and the width direction. However, the triangular shape of the magnet 150 causes distortion of the magnet, and thus the components 140 in the feed region turn to tilt in the feed direction and the width direction. On the contrary, for the L-shaped magnet 150 of
Hereinafter, a magnet 150 according to Comparative Example 2 of this embodiment will be described.
The magnet 150 according to this comparative example differs from the magnet 150 of
A plan view and a sectional view of
The components 140 fed to the feed region are also attracted towards the feed and the width direction in the feed region by the magnet 150 according to this comparative example, and thereby move to the ends of the component storage units 141 in the feed direction and the width direction. However, since the component 140 approaching the component take-out position is attracted to the front in the feed direction by the U-shape of the magnet 150, the position of the component 140 at the component take-out position is not fixed at the end in the feed direction. On the contrary, for the L-shaped magnet 150 of
The tape feeder and the carrier tape feeding method using the tape feeder according to the invention have been described above with reference to the embodiment, although the invention is not limited to this embodiment. Various modifications thought by those skilled in the art within a range not departing from the spirits of the invention are included in a range of the invention. Moreover, any of the components in the embodiment may be combined together within the range not departing from the spirits of the invention.
For example, in the embodiment described above, the magnet 150 is L-shaped. However, the magnet 150 is not limited to this as long as it generates a magnetic force of attracting the components 140 in the feed region to the ends of the component storage units 141. For example, the magnet 150 may be formed of the first magnet 151 and the second magnet 152 separated from each other.
Moreover, in the embodiment described above, the second magnet 152 is so provided as to be separated from the component storage unit 141 at the component take-out position by the distance sandwiching the two component storage units 141, although not the magnet 152 is limited to this as long as it can is separated by a distance that does not impede the component take-out by the absorbing nozzle with consideration given to, for example, a magnetic force of the second magnet 152 and the component pitch. For example, in a case where the magnetic force of the second magnet 152 is strong, the second magnet 152 may be provided below the component storage unit 141 next to the component storage unit 141 at the component take-out position. In a case where the magnetic force of the second magnet 152 is weak, the second magnet 152 may be so provided as to be separated from the component storage unit 141 at the component take-out position by a distance sandwiching the three or more component storage units 141.
Moreover, in the embodiment described above, the first magnet 151 is provided below the bottom surfaces of the component storage units 141 in the feed region so as to cover the half areas of the bottom surfaces of the component storage units 141. However, the first magnet 151 may be provided below the bottom surfaces of the component storage units 141 in the feed region so as to cover not all but only part of the bottom surfaces of the component storage units 141 in the width direction, without being limited to the half areas.
Moreover, in the embodiment described above, the first magnet 151 is provided below the bottom surfaces of the three component storage units 141 fed to the feed region, although the number is not limited to 3 as long as the first magnet 151 is provided below the bottom surfaces of the plurality of component storage units 141 fed to the feed region.
Moreover, in the embodiment described above, the first magnet 151 is provided. However, the first magnet 151 is not limiting as long as the tape feeder has a first magnetic force region which is provided below the bottom surfaces of the component storage units 141 fed to the feed region so as to extend in the feed direction below one side of the bottom surfaces in the width direction and which attracts the components of the component storage units 141 fed to the feed region to one side in the width direction. For example, in the embodiment described above, the first magnetic force region is formed of one first magnet 151 but may be formed of a plurality of magnets.
Moreover, in the embodiment described above, the second magnet 152 is provided. However, the second magnet 152 is not limiting as long as the tape feeder has a second magnetic force region which is provided at the back in the feed direction with respect to the first magnetic force region below the bottom surfaces of the component storage units 141 fed to the feed region and which attracts the components of the component storage units 141 fed to the feed region to the back in the feed direction. For example, in the embodiment described above, the second magnetic force region is formed of one second magnet 152 but may be formed of a plurality of magnets.
Moreover, in the embodiment described above, vibration is added to the tape feeder before the components 140 are attracted to the ends of the component storage units 141 by the magnet 150. Alternatively, the tape feeder may be tilted to thereby move the components 140 to the ends of the component storage units 141.
For example, as shown in
Configuration of
Although only some exemplary embodiments of this invention have been described in detail above, those skilled in the art will readily appreciate that many modifications are possible in the exemplary embodiments without materially departing from the novel teachings and advantages of this invention. Accordingly, all such modifications are intended to be included within the scope of this invention.
The present invention can be used for a tape feeder and a carrier tape feeding method using the tape feeder, and can be used especially for a component mounting machine, etc.
Number | Date | Country | Kind |
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2010-009476 | Jan 2010 | JP | national |
This is a continuation application of PCT application No. PCT/JP2011/000253 filed on Jan. 19, 2011, designating the United States of America.
Number | Date | Country | |
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Parent | PCT/JP2011/000253 | Jan 2011 | US |
Child | 13225772 | US |