JP2008053381A - Tape feeder and mounting machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mounting machine which can reduce waste of the components. <P>SOLUTION: When a component X is fed out to a pickup position 53 but the suction operation is not performed under various situations, inversion feed operation is performed for returning the component X fed out to the pickup position 53 back to the upstream side in the tape feed direction from the pickup position 53. Consequently, the same component X is not refed to the pickup position 53 and discarded at the time of next pickup, thus reducing waste of the components. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a tape feeder and a mounting machine that are attached to a mounting machine and supply electronic components.

  2. Description of the Related Art Conventionally, a tape feeder is known as a component supply device that is attached to a mounting machine for mounting electronic components on a substrate and supplies the electronic components to the mounting machine.

For example, as shown in Patent Document 1 below, such a tape feeder is provided with a reel on which a tape for holding components at regular intervals is wound, and the tape drawn from the reel is transferred to a transfer head of a mounting machine. Thus, the electronic component is fed to a pickup position where the electronic component is picked up. The tape that holds the electronic component is engaged with a sprocket included in the tape feeder, and the sprocket is intermittently rotated at a predetermined feed amount so that the electronic component held on the tape is sequentially moved to the pickup position. To come to reach.
JP-A-7-242284

  However, in such a mounting machine, the suction operation may not be performed for various reasons even if the component is sent to the pickup position. For example, if the transfer head fails to pick up the component at the pickup position, or if only the feed operation is performed without picking up the component to check the stability of the component feed operation, etc. This is a case where the tape feeder is removed from the mounting machine and replaced in a state where the feed is sent out. In such a case, the parts once sent to the pickup position are usually discarded and the parts are wasted.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a tape feeder capable of reducing the waste of parts.

The present invention provides the following means. That is,
[1] A sprocket that engages with a tape that holds parts at predetermined intervals, a motor that rotationally drives the sprocket to send the tape to a predetermined pickup position, and a controller that controls driving of the motor. ,
The controller drives the motor in the forward direction to sequentially feed the parts held on the tape to the pickup position, and the controller reverses the motor to send the parts to the pickup position from the pickup position. A tape feeder that performs a reverse feed operation to return to the upstream side in the tape feed direction.

  [2] The tape feeder according to [1], wherein, in the reverse feed operation, the tape can be returned by a plurality of frames with an interval between parts held on the tape as one frame.

  [3] When the controller receives a removal command to remove the tape feeder from the mounting machine, the controller reverses the part sent to the position immediately before the pickup position in the pickup position or the tape feeding direction to the cover position where it is not exposed to the outside. 3. The tape feeder according to 1 or 2 above, which performs a feeding operation.

  [4] The controller stores a return amount in the reverse feed operation in response to the removal command, and when the tape feeder is attached to the mounting machine later, the tape feed is based on the stored return amount. 4. The tape feeder according to item 3, wherein the operation is performed.

[5] Image pickup means for picking up an image near the pickup position,
When the controller receives an instruction to remove the tape feeder from the mounter, the controller performs the reverse feed operation so that the leading part reaches the cover position based on the image captured by the imaging unit. The tape feeder described.

[6] A mounting machine to which the tape feeder according to item 3 can be attached,
When the tape feeder is removed from the mounting machine, the return amount in the reverse feed operation is stored in association with the identification information for specifying the tape feeder,
When the tape feeder is attached to the mounting machine, the tape feeder is caused to perform the tape feeding operation based on the return amount stored in association with the identification information of the tape feeder. A mounting machine.

[7] A mounting machine to which the tape feeder according to item 3 can be attached,
Comprising imaging means for imaging the vicinity of the pickup position of the tape feeder;
When the tape feeder is attached to the mounting machine, the image pickup means images the vicinity of the pickup position of the tape feeder, and the leading component in the picked-up image is the pickup position or the pickup position in the tape feed direction. A mounting machine that causes the tape feeder to perform the tape feeding operation so as to reach the position immediately before the position.

  According to the above invention [1], since the part once sent to the pickup position by the reverse feed operation can be returned to the upstream side from the pickup position, such a part can be reused and the waste of parts can be reduced. can do.

  According to the above invention [2], a plurality of parts fed downstream from the pickup position even when a tape feeding operation for a plurality of frames is performed for confirmation of the stability of the tape feeding operation. Can be prevented from being wasted by returning it to the upstream side from the pickup position.

  According to the invention [3], even when there is a part that has been sent to the pickup position or the position immediately before it when the tape feeder is attached to the mounting machine, such a part is removed when the tape feeder is removed from the mounting machine. Since the reverse feed operation is performed to return the cover to the cover position where it is not exposed to the outside, it is possible to prevent a situation where the parts fall off when the tape feeder is removed.

  According to the above invention [4], when the tape feeder removed from the mounting machine is attached to the mounting machine again, the tape feeding operation is performed based on the return amount when the tape feeder is removed. The production of the substrate using the feeder can be started immediately.

  According to the invention [5], when the tape feeder is removed from the mounting machine, the leading part can be reliably returned to the cover position, and the situation where the part falls when the tape feeder is removed can be prevented. be able to.

  According to the above invention [6], when the tape feeder removed from the mounting machine is attached to the mounting machine again, the tape feeding operation is performed based on the return amount when the tape feeder is removed. The production of the substrate using the feeder can be started immediately.

  According to the above invention [7], when the tape feeder is attached to the mounting machine, the tape feeding operation is performed so that the leading component in the captured image near the pickup position reaches the pickup position or the position immediately before it. Therefore, the production of the substrate using the attached tape feeder can be started promptly.

  FIG. 1 is a plan view showing a mounting machine according to an embodiment of the present invention. As shown in this figure, the mounting machine 10 includes conveyors 20 and 20 that are arranged on the base 11 and convey the printed circuit board P, and component supply units 30 that are arranged on both sides of the conveyors 20 and 20. And an electronic component mounting head unit 40 provided above the base 11.

  The head unit 40 is movable in a region extending between the component supply unit 30 and the mounting position on the substrate P so that an electronic component can be picked up from the component supply unit 30 and mounted on the substrate P. Specifically, the head unit 40 is supported by a head unit support member 42 extending in the X axis direction (substrate transport direction of the conveyor 20) so as to be movable in the X axis direction. The guide rails 43 and 43 extending in the Y-axis direction (a direction orthogonal to the X-axis in the horizontal plane) are supported so as to be movable in the Y-axis direction. The head unit 40 is driven in the X-axis direction by the X-axis motor 44 via the ball screw shaft 45, and the head unit support member 42 is driven in the Y-axis direction by the Y-axis motor 46 via the ball screw shaft 47. Driving is performed.

  In addition, a plurality of heads 41 are mounted on the head unit 40 side by side in the X-axis direction. Each head 41 is driven in the vertical direction (Z-axis direction) by an elevating mechanism using a Z-axis motor as a drive source, and is driven in the rotation direction (R-axis direction) by a rotation drive mechanism using an R-axis motor as a drive source. It has come to be.

  At the tip of each head 41, a suction nozzle for picking up electronic components and mounting them on the substrate is provided. Each nozzle is supplied with a negative pressure from a negative pressure means (not shown) at the time of component suction, and can pick up an electronic component by suction with the suction force of the negative pressure. Each nozzle is provided with a pressure sensor (not shown) for detecting the negative pressure level. This pressure sensor can determine whether or not each nozzle has successfully picked up (sucked) a component from the change in negative pressure at each nozzle, and functions as a pickup success / failure determination means.

  The head unit 40 is provided with a board photographing camera 48 made up of a CCD camera or the like equipped with illumination, for example. The board photographing camera 48 can photograph a position reference mark and a board ID mark provided on the board P carried into the mounting machine 10. The board photographing camera 48 functions as an image pickup means for photographing the vicinity of the pickup position of the electronic component in each tape feeder 50 attached to the component supply unit 30.

  The component supply sections 30 are provided at a total of four locations on the upstream side and the downstream side of the conveyors 20 and 20, respectively. A plurality of tape feeders 50 as component supply devices can be arranged in parallel on the feeder plate 31 and attached to each component supply unit 30.

  Further, between the component supply units 30 and 30 divided into the upstream side and the downstream side, component photographing cameras 12 and 12 are provided on both the front side and the rear side. The component imaging cameras 12 and 12 image the component sucked by the head unit 40, and detect a positional deviation of the component with respect to the suction nozzle. The component photographing cameras 12 and 12 can determine whether or not each suction nozzle has succeeded in picking up (sucking) the component based on the presence or absence of the component sucked by the suction nozzle. Together with the sensor, it functions as a pickup success / failure determination means.

  FIG. 2 is a schematic configuration explanatory diagram of a tape feeder according to an embodiment of the present invention. FIG. 3 is a perspective view of the front portion of the tape feeder. FIG. 4 is a plan view showing an example of a component supply tape attached to the tape feeder.

  The tape feeder 50 according to this embodiment is configured as an electric component supply device including a motor 51 as a drive source.

  A reel 61 around which a tape 60 holding electronic components is wound is attached to the tape feeder 50, and the tape 60 pulled out from the reel 61 is fed and driven by a sprocket 52 that is driven to rotate by a motor 51. The

  The tape 60 is provided with component pockets 62 for storing and holding small pieces of components 64 such as ICs and transistors at predetermined intervals, and at the same pitch right next to the center of the component pocket 62 in the feed direction. 63... Are provided. The interval (pitch) of the parts 64... On the tape 60 is hereinafter referred to as one frame. A cover tape 60 a is provided on the upper surface side of the tape 60 so as to cover the opening of the component pocket 62.

  The sprocket 52 of the tape feeder 50 is provided with pins 54 that protrude in the radial direction at the same pitch as the tape feed holes 63. Each pin 54 provided in the sprocket 52 meshes with a feed hole 63 provided in the tape 60 to feed and drive the tape 60. And each electronic component 64 ... hold | maintained at the tape 60 is sequentially sent to the predetermined pick-up position 53 picked up by the head unit 40. FIG.

  A tape guide member 56 that guides the traveling tape 60 is provided at the upper portion of the front portion of the tape feeder 50, and the pickup position 53 is set in an exposed hole portion 56b provided in the tape guide member 56. Yes. A cover tape discharge hole 56a that peels and discharges the cover tape 60a from the tape main body 60b is provided upstream of the exposed hole portion 56b in the tape running direction.

  In the tape guide member 56, a portion between the cover tape discharge hole 56a and the exposed hole portion 56b where the pickup position 53 is set is a tape cover portion that covers the upper part of the component pocket 62 ... from which the cover tape 60a is peeled off. 57 to prevent the parts 64 in the part pockets 62 from being exposed to the outside. In this embodiment, a portion that is prevented from being exposed to the outside by the tape guide member 56 upstream of the tape cover portion 57 or the cover tape discharge hole 56a is referred to as a cover position.

  The motor 51 that rotationally drives the sprocket 52 is configured by a servo motor or the like that can rotate in both forward and reverse directions and can control the rotation angle (phase). The motor 51 is rotationally controlled according to a control signal from a controller 55 provided in the tape feeder 50.

  The controller 55 performs a tape feeding operation of sequentially feeding the components 64... Held on the tape 60 to the pickup position 53 by driving the motor 51 forward. Further, the controller 55 may perform a reverse feed operation for returning the parts 64... Fed to the pickup position 53 or the downstream side thereof to the upstream side from the pickup position 64 by driving the motor 51 in the reverse direction as needed. It can be done. This reverse feed operation will be described later.

  Further, in the tape feeder 50, the controller 55 on the tape feeder 50 side is electrically connected to the controller 15 on the mounting machine 10 side in a state of being attached to the mounting machine 10, and the driving power of the motor 51 and the like is supplied to the mounting machine. In addition to being supplied from the 10 side, a drive control signal of the motor 51 and the like are transmitted to and received from the mounting machine 10 side.

  Hereinafter, a component mounting operation in the mounting machine 10 will be described.

  FIG. 5 is a flowchart showing a procedure of component mounting operation in the mounting machine according to the present embodiment. FIG. 6 is an explanatory diagram when the component pick-up fails in the mounting operation.

  As shown in FIG. 5, in the component mounting operation of the mounting machine 10, a tape feeding operation is first performed (step S10), and the component pickup picked up by picking up the component 64 sent to the pickup position 53 with the suction nozzle. An operation is performed (step S11).

  Subsequently, it is determined whether or not this part has been successfully picked up (step S12). In this embodiment, the success or failure of the pickup is determined by the negative pressure value of each nozzle detected by the pressure sensor functioning as a pickup success / failure determination unit, and the suction nozzle in the elevating mechanism that drives each head 41, that is, the suction nozzle in the Z-axis direction. With the vertical position data value, the suction nozzle descends to the suction position at the pickup position 53, and after the negative pressure value rises in a state where the component is in contact with the tip of the suction nozzle, the suction nozzle moves to a predetermined amount at the pickup position 53. Judgment is made based on whether or not the increased negative pressure value will decrease in the increased state. If the increased negative pressure value is maintained while the suction nozzle is raised by a predetermined amount at the pickup position 53, the pickup is successful, and the suction nozzle is moved onto the component photographing cameras 12, 12 by the head unit 40. At this time, it is determined whether or not the component has fallen from the suction nozzle during horizontal movement based on the result of photographing the component sucked by the suction nozzle photographed by the component photographing cameras 12 and 12.

  If the component has been successfully picked up (YES in step S12), the component picked up by the suction nozzle is mounted on the substrate (step S13). If all the components have not been mounted on the board, the above operation is repeated (YES in step S14), and if completed, the process ends (NO in step S14).

  On the other hand, if the pickup of the component has failed (NO in step S12), the component X that should have been picked up at the pickup position 53 remains as shown in FIG. In this case, as shown in FIG. 6B, a reverse feed operation is performed to return the part X to the immediately preceding position upstream by one frame (interval of the parts 64 on the tape 60) in the tape feed direction from the pickup position 53. (Step S15), it returns to the operation step for mounting the next component.

  In this way, the part X that has failed to be picked up by the next tape feeding operation (step S10) is re-supplied to the pick-up position 53 and reused at the next pick-up as shown in FIG. 6C. It is possible to prevent parts that have failed to be picked up from being wasted.

  Next, for each tape feeder 50 attached to the mounting machine 10, a case where only the tape feeding operation is performed without picking up the components in order to confirm the stability of the component feeding operation and the like will be described.

  FIG. 7 is a flowchart showing an operation procedure when the tape feeding operation is performed without picking up the components in the mounting machine according to the present embodiment. FIG. 8 is an explanatory diagram of the operation.

  As shown in FIG. 7, the operation of confirming the stability of the parts feeding operation, etc. is performed by an operator or the like forcing the tape feeding operation to the input switch provided on the tape feeder 50 or the input operation unit on the mounting machine 10 side. This is because the forced tape feed input is input (step S20).

  When this forced tape feed input is performed (YES in step S20), the tape feeder 50 performs a tape feed operation that does not involve the pickup operation of the component 64 at the pickup position 53 (step S21), and the tape feed operation is performed by an operator or the like. Is confirmed visually. At this time, the controller 55 of the tape feeder 50 counts and stores the tape feed amount (number of frames) by the tape feed operation based on the forced tape feed input (step S22).

  Normally, confirmation of the stability of the parts feeding operation is performed by repeating such a tape feeding operation a plurality of times. As a result, for example, as shown in FIG. The part 64 is left on the downstream side from the pickup position 53 by the number of times of the tape feeding operation (number of frames) repeatedly performed without accompanying.

  After the tape feeding has been performed an arbitrary number of times by an operator or the like, the operation of the mounting machine 10 is resumed by an operator or the like using an input switch provided on the tape feeder 50 or an input operation unit on the mounting machine 10 side. This is because the tape return input is performed (step S23).

  Until this tape return input is performed, the above-described forced tape feed input and tape return input are repeatedly waited (NO in steps S20 and S23).

  When the tape return input is performed (YES in step S23), the reverse feed operation for a plurality of frames is performed based on the feed amount (number of frames) obtained by counting the tape feed operation by the forced tape feed input (step S24). ), Resumption of operation is permitted (step S25).

  If it is assumed that the operator does not necessarily perform the tape return input, the time elapsed from the forced tape feed input exceeds the predetermined time in the determination of step S23 when there is no tape return input. If it does not exceed, the process proceeds to step S20. If it exceeds, the monitor device (not shown) indicates that there is no tape return input, and resumption of operation is permitted. (Step S25).

  In the example of FIG. 8A, if the leading part X on the tape 60 is at the immediately preceding position 53b upstream of the pickup position 53 by one frame (interval of the parts 64 on the tape 60) before feeding the tape in the example of FIG. This leading part X has been sent out for three frames from here. In this case, three frames are stored as the feed amount. Accordingly, when the reverse feeding operation for three frames is performed, the leading part X returns to the position 53b immediately before the pickup position 53, which is the same as before the tape feeding, as shown in FIG. 8B.

  Thus, if the tape feeding operation is performed at the time of picking up the next part, the leading part X is sent out to the pickup position 53 and used. Therefore, even when the tape feeding without the pickup is performed to check the stability of the parts feeding operation and the like, the parts sent to the downstream side of the pickup position 53 are wasted and discarded. It is possible to use it effectively.

  Next, in the mounting machine 10, a case will be described in which the tape feeder 50 attached is removed and attached again when the type of board to be produced is changed.

  FIG. 9A is a flowchart showing an operation procedure when the tape feeder is removed in the mounting machine according to the present embodiment, and FIG. 9B is a flowchart showing the operation procedure when the tape feeder is similarly attached. FIG. 10 is an explanatory diagram of these operations.

  As shown in FIG. 10, here, the pickup position 53 is set downstream of the position immediately after in the tape feed direction with respect to the cover position that is prevented from being exposed to the outside by the tape cover portion 57. An example will be described.

    As shown in FIG. 9A, removal of the tape feeder 50 from the mounting machine 10 is started by inputting a feeder removal command issued from the controller 15 of the mounting machine 10 or a removal command by an operator or the like (step S30). ). An input by an operator or the like is performed on, for example, an input switch provided in the tape feeder 50 or an input operation unit on the mounting machine 10 side, and transmitted to the controller 55 of the tape feeder 50.

  Upon receiving this feeder removal command, the controller of the tape feeder 50 performs a reverse feed operation with the number of frames that can return the component sent to the pickup position to the cover position where it is not exposed to the outside (step S31), and stores the number of reverse frames. (Step S32).

  The number of reverse frames may be stored by the controller 55 of the tape feeder 50 or the controller 15 on the mounting machine 10 side. When the controller 15 on the mounting machine 10 side stores, the tape feeder is stored in association with identification information such as a feeder number that can identify the tape feeder.

  In the example of FIG. 10, the leading part X is sent to the pickup position 53 at the time of FIG. In this case, as shown in FIG. 10B, the reverse feed operation of a plurality of frames is performed up to the cover position 57 a where the leading part X is hidden by the tape cover portion 57.

  A predetermined number of frames may be set in advance as the return amount of the reverse feed operation. Further, the return amount may be set based on the position information of the leading part when the tape feeder 50 is removed.

  In FIG. 10B, the leading part X is returned to the most downstream position of the cover position 57a, but a reverse feed operation may be performed so as to return further to the upstream side.

  When the feeder removal command is received, the leading part is not the part X at the pickup position 53 but the part Y immediately before the pickup position 53 (in the case where the part X does not exist in FIG. 10A). ) May be performed by performing a reverse feed operation for the number of frames in which the component Y immediately before the pickup position 53 returns to the cover position 57a.

  If the part X sent to the pickup position 53 in this way or the part Y at the position 53b immediately before is returned to the cover position 57a, the controller 55 of the tape feeder 50 permits the removal of the tape feeder 50. An operator or the like is notified through a display unit provided in the tape feeder 50 or a monitor screen provided in the mounting machine 10 (step S33). In response to this, the operator or the like executes an operation of removing the tape feeder 50 from the mounting machine 10 (step S34).

  When the tape feeder 50 is removed from the mounting machine 10 in this way, a reverse feed operation is performed. Therefore, when the tape feeder 50 is attached to the mounting machine, the part that has been sent to the pickup position 53 or the position immediately before it is picked up. Even if there is 64, it is possible to prevent such a part from dropping when the tape feeder 50 is removed by returning to the cover position 57a that is not exposed to the outside.

  As shown in FIG. 9B, the attachment of the tape feeder 50 to the mounting machine 10 is started when the tape feeder 50 is actually attached to the mounting machine 10 by an operator or the like (step S40).

  When the mounting machine 10 or the tape feeder 50 itself detects that the tape feeder 50 is attached to the mounting machine 10 (step S41), the controller 55 of the tape feeder 50 or the controller 15 of the mounting machine 10 causes the tape feeder 55 to be installed. It is determined whether or not the return amount (number of reverse frames) at the time when is removed is stored (step S42). When the determination is made by the controller 15 on the mounting machine 10 side, the identification information of the attached tape feeder 50 is read, and the presence or absence of the return amount stored in association with the identification information is determined.

  If the return amount (reverse frame number) is stored (YES in step S42), the tape feeding operation is performed according to the stored reverse frame number (step S43), and the operation is resumed. Allowed (step S44).

  In the example of FIG. 10, the head part X at the pickup position 53 is returned by two frames by the reverse feed operation from FIG. 10A to FIG. 10B, but the part feed operation is performed before the part pick-up operation. In FIG. 10C, the tape feeding operation for one frame is performed by subtracting one frame from the return amount so that the leading part X is fed back to the position 53b immediately before the pickup position 53. It has been broken.

  In the case where the component feeding operation is not performed before the component pickup operation, the tape feeding operation may be performed for two frames as the return amount so that the leading component X reaches the pickup position 53.

  Alternatively, when the leading part is at the position 53b immediately before the pickup position 53 when the tape feeder 50 is removed, and the leading part is sent back to the position 53b immediately before the pickup position 53, the same frame as the return amount is used. It is sufficient to perform the tape feeding operation by the number.

  On the other hand, if the number of reverse frames is not stored in the tape feeder 50 (NO in step S32), in principle, resumption of operation is permitted as it is (step S34). In this case, there is a possibility that the part has not reached the pickup position 53 or the position 53b just before it, but the part can be supplied by forcibly feeding the tape until the leading part is fed to these positions. The state can be realized.

  Even when the number of reverse frames is not stored, it is expected that the leading part is fed to the pickup position 53 or the position 53b immediately before it by automatically performing the tape feeding operation for a predetermined number of frames. May be realized.

  As described above, when the tape feeder 50 removed from the mounting machine 10 is attached to the mounting machine 10 again, the tape feeding operation is performed based on the return amount when the tape feeder 50 is removed. The production of the substrate using the feeder 50 can be started quickly.

  Next, another example of the procedure for removing and attaching the tape feeder 50 will be described. In the following, detailed description of the same parts as in the above-described example of FIG. 9 will be omitted, and different parts will be described.

  FIG. 11A is a flowchart showing another example of the operation procedure for removing the tape feeder in the mounting machine according to the present embodiment, and FIG. 11B is another example of the operation procedure for attaching the tape feeder. It is a flowchart which shows.

  As shown in FIG. 11A, also in this other example, the removal of the tape feeder 50 from the mounting machine 10 is started by the input of a removal command by the controller 15 of the mounting machine 10 or an operator (step S50). .

  The feeder removal command is transmitted to the controller 15 of the mounting machine 10, and the controller 15 of the mounting machine 10 removes the board photographing camera 48 that functions as an imaging unit attached to the head unit 40. The vicinity of the pickup position 53 is moved to a position for imaging (step S51).

  Then, while imaging the vicinity of the pick-up position 53 of the tape feeder 50, in the picked-up image, the leading part at the pick-up position 53, the position 53b just before it or another position is at the cover position 57a hidden by the tape cover portion 57 Until it reaches (NO in step S53), the tape feeder 50 is caused to perform reverse feed operation one frame at a time (step S52).

  If the head part is returned to the cover position 57a until it is hidden (YES in step S53), the controller 15 of the mounting machine 10 indicates that the removal of the tape feeder 50 is permitted. An operator or the like is notified via a monitor screen or the like provided in 10 (step S54), and in response to this, the operator or the like executes an operation of removing the tape feeder 50 from the mounting machine 10 (step S55).

  In this way, when the tape feeder 50 is removed from the mounting machine 10, the leading part can be reliably returned to the cover position, so that when the tape feeder 50 is removed, the part is dropped. Can be prevented.

  As shown in FIG. 11B, also in this other example, the attachment of the tape feeder 50 to the mounting machine 10 is started when the tape feeder 50 is actually attached to the mounting machine 10 by an operator or the like ( Step S60).

  When the mounting machine 10 or the tape feeder 50 itself detects that the tape feeder 50 is attached to the mounting machine 10 (step S61), the controller 15 of the mounting machine 10 functions as an imaging unit attached to the head unit 40. The board photographing camera 48 to be moved is moved to a position for photographing the vicinity of the pickup position 53 of the attached tape feeder 50 (step S62).

  Then, while imaging the vicinity of the pickup position 53 of the tape feeder 50, until the leading part comes out at the pickup position 53 or the position 53b immediately before it in the captured image (NO in step S64), the tape feeder 50 is loaded. Then, the tape feeding operation is performed one frame at a time (step S63).

  If the head part comes out to the pickup position 53 or the position 53b immediately before it (YES in step S64), the controller 15 of the mounting machine 10 permits the operation restart using the tape feeder 50 (step S65).

  In this way, when the tape feeder 50 is attached to the mounting machine 10, the tape feeding operation is performed so that the leading component reaches the pickup position 53 or the position 53b immediately before it, so that the attached tape feeder 50 is attached. Production of a substrate using can be started immediately.

  Further, since it is determined in the picked-up image near the pickup position 53 that the leading part has reached the pickup position 53 or just before the position 53b, the leading part can be reliably sent to the pickup position 53 or just before the position 53b. .

  As described above, the present invention has been described based on the embodiment, but the present invention is not limited to the above-described configuration, and may be appropriately changed without departing from the gist of the present invention.

It is a top view which shows the mounting machine concerning one Embodiment of this invention. It is a schematic structure explanatory view of a tape feeder concerning one embodiment of the present invention. It is a perspective view of the front part of the tape feeder. It is a top view which shows an example of the component supply tape attached to the same tape feeder. It is a flowchart which shows the procedure of the component mounting operation | movement in the mounting machine concerning this embodiment. It is explanatory drawing when the picking-up of components fails in the mounting operation. It is a flowchart which shows the operation | movement procedure at the time of performing tape feeding operation | movement, without picking up components in the mounting machine concerning this embodiment. It is explanatory drawing of the operation | movement. (A) is a flowchart which shows the operation | movement procedure when a tape feeder is similarly attached when a tape feeder is removed in the mounting machine concerning this embodiment. It is explanatory drawing of these operation | movement. (A) is a flowchart which shows the other example of the operation | movement procedure which removes a tape feeder in the mounting machine concerning this embodiment, (b) is a flowchart which shows the other example of the operation | movement procedure to which a tape feeder is similarly attached. is there.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Mounting machine 15 Controller 40 Head unit 41 Head 48 Board | substrate photography camera (imaging means)
50 Tape feeder 51 Motor 52 Sprocket 53 Pickup position 53b Immediate position 55 Controller 56 Tape guide member 57 Tape cover part 57a Cover position 60 Tape 64 Parts

Claims (7)

A sprocket that engages with a tape that holds parts at predetermined intervals, a motor that rotationally drives the sprocket to send the tape to a predetermined pickup position, and a controller that controls driving of the motor,
The controller drives the motor in the forward direction to sequentially feed the parts held on the tape to the pickup position, and the controller reverses the motor to send the parts to the pickup position from the pickup position. A tape feeder that performs a reverse feed operation to return to the upstream side in the tape feed direction.   2. The tape feeder according to claim 1, wherein, in the reverse feed operation, the tape can be returned by a plurality of frames with an interval between parts held on the tape as one frame.   When the controller receives a removal command to remove the tape feeder from the mounting machine, the controller performs a reverse feed operation to return the parts sent to the position immediately before the pickup position in the pickup position or the tape feed direction to a cover position that is not exposed to the outside. The tape feeder according to claim 1 or 2 to be performed.   The controller stores a return amount in the reverse feed operation performed in response to the removal command, and when the tape feeder is attached to the mounting machine later, the tape is based on the stored return amount. The tape feeder according to claim 3 which performs a feeding operation. Comprising imaging means for imaging the vicinity of the pickup position;
5. The controller performs the reverse feed operation so that a leading part reaches the cover position based on an image captured by the imaging unit when receiving an instruction to remove the tape feeder from the mounting machine. The tape feeder described in 1. A mounting machine to which the tape feeder according to claim 3 can be attached,
When the tape feeder is removed from the mounting machine, the return amount in the reverse feed operation is stored in association with the identification information for specifying the tape feeder,
When the tape feeder is attached to the mounting machine, the tape feeder is caused to perform the tape feeding operation based on the return amount stored in association with the identification information of the tape feeder. A mounting machine. A mounting machine to which the tape feeder according to claim 3 can be attached,
Comprising imaging means for imaging the vicinity of the pickup position of the tape feeder;
When the tape feeder is attached to the mounting machine, the image pickup means images the vicinity of the pickup position of the tape feeder, and the leading component in the picked-up image is the pickup position or the pickup position in the tape feed direction. A mounting machine that causes the tape feeder to perform the tape feeding operation so as to reach the position immediately before the position.

Images