JP6543813B2 - Cartridge for electronic component mounting device - Google Patents

Description

  The present invention relates to a cartridge for an electronic component mounting apparatus incorporating a filter for filtering air, which is used in an electronic component mounting apparatus for holding an electronic component and mounting it on a substrate by applying a negative pressure to a suction hole of a nozzle. It is a thing.

  In the component mounting field where an electronic component is mounted on a substrate to produce a mounting substrate, a method in which electronic components are adsorbed and held by negative pressure by a nozzle provided on a mounting head of the electronic component mounting device is widely used . In this type of electronic component mounting apparatus, the nozzle can be replaceably mounted on the nozzle holder provided on the nozzle shaft provided in the mounting head, whereby the shape and size of the electronic component to be operated can be obtained. It is possible to attach and detach the nozzle for the purpose of changing the type of the nozzle according to the situation or for maintenance. And in these nozzles, a filter for filtering foreign substances in the sucked air is built in (for example, refer to patent documents 1 and 2).

  In the prior art shown in Patent Document 1, from the nozzle 21 to the filter holder 22 formed at a position where the lower end of the head main body 20 is a nozzle holder and the vent 20a of the head main body 20 is opened at the lower end. An example is described in which a filter 30 for filtering suctioned air is detachably mounted. Further, in the prior art shown in Patent Document 2, in the vacuum suction nozzle 2 mounted on the nozzle holder, the inside of the nozzle main body (flange 3) provided with a storage portion for storing the suction shaft (one end 2c) in a projecting manner Describes a configuration for housing the filter 4.

JP 2008-34410 A Unexamined-Japanese-Patent No. 2012-143861

  The prior art shown in the above-mentioned patent document example had the following subjects resulting from the mounting structure of the filter for filtration of a foreign material. First, in the prior art, since the filter is mounted inside the nozzle, restrictions on the shape and size of the filter can not be avoided, and a structure in which a small-sized filter is mounted on a narrow area can not be avoided. Absent. As a result, there is a problem in that the working life is shortened because a sufficient filtration surface can not be secured in the filter, and the workability at the time of attachment and detachment for maintenance and replacement is poor. In addition, in the component mounting field, miniaturization of electronic components has progressed, and as a result, a nozzle for holding the electronic components and a nozzle holder for holding the nozzles are required to be smaller and smaller than before. However, the configuration for realizing such a request is not disclosed in the prior art including the above-mentioned patent document example, and a new measure has been required.

  Therefore, in the present invention, in a configuration including a cartridge having a filter for detachably holding a nozzle holding an electronic component by negative pressure on a nozzle holder and filtering air sucked from the nozzle, the filter is used together with the miniaturization of the nozzle holder. It is an object of the present invention to provide a cartridge for an electronic component mounting apparatus capable of improving filtration performance and workability at the time of attachment and detachment.

The cartridge for the electronic component mounting apparatus according to the present invention has a first suction path having a tip end and a mounting portion and penetrating from the tip to the mounting portion, and is introduced into the first suction path. The mounting portion is inserted into an insertion hole provided in communication with the nozzle holding the electronic component at the tip end portion by the negative pressure and the second suction path connected to the negative pressure generation source, and the nozzle A cartridge for an electronic component mounting apparatus which is used in an electronic component mounting apparatus provided with a nozzle holder for detachably holding the cartridge, and which is mounted on the nozzle holder in a state of being inserted into the insertion hole, A filter holder having an insertable external dimension and having an internal space penetrating from one end to the other end; a filter disposed in the internal space and filtering air drawn from the first suction passage; An annular packing that is disposed at the one end of the filter holder and that airtightly connects the second suction path and the internal space by abutting on a stopper provided at the back of the insertion hole; disposed on the other end of the holding member, wherein inserted in the insertion hole made of an elastic member that connects the first suction path and the inner space airtight by contact to the mating attachment section pad portion The filter has a base in contact with the inner wall at one end of the filter holder, the base of the filter protrudes from one end of the filter holder, and the packing is on the protrusion It is held .

  According to the present invention, in the configuration provided with the cartridge having the filter for filtering the air drawn in from the nozzle, it is possible to miniaturize the nozzle holder and to improve the filtration performance of the filter and the workability at the time of attachment and detachment.

The perspective view which shows the whole structure of the electronic component mounting apparatus of one embodiment of this invention Structure explanatory drawing of the mounting head used for the electronic component mounting apparatus of one embodiment of this invention Partial cross-sectional view of a mounting head used in an electronic component mounting apparatus according to an embodiment of the present invention Front view of nozzle holder in main shaft used in electronic component mounting apparatus of one embodiment of the present invention Side view of the nozzle holder in the main shaft used in the electronic component mounting apparatus of one embodiment of the present invention Sectional view of a nozzle holder in a main shaft used in an electronic component mounting apparatus according to an embodiment of the present invention The perspective view of the nozzle holder in the main shaft used for the electronic component mounting apparatus of one embodiment of the present invention Sectional drawing of the holder cylinder part of the nozzle holder in the main shaft used for the electronic component mounting apparatus of one embodiment of this invention Sectional view of a nozzle holder in a main shaft used in an electronic component mounting apparatus according to an embodiment of the present invention Sectional drawing which shows the cartridge removal state in the nozzle holder used for the electronic component mounting apparatus of one embodiment of this invention A partial side view of a shaft connecting portion of a main shaft used in an electronic component mounting apparatus according to an embodiment of the present invention The partial perspective view which shows the structure of the shaft connection part of the main shaft used for the electronic component mounting apparatus of one embodiment of this invention Partial cross-sectional view of a shaft connecting portion of a main shaft used in an electronic component mounting apparatus according to an embodiment of the present invention Functional explanatory view of a shaft connecting portion of a main shaft used in an electronic component mounting apparatus according to an embodiment of the present invention

  Next, embodiments of the present invention will be described with reference to the drawings. First, the structure of the electronic component mounting apparatus 1 will be described with reference to FIG. Hereinafter, the substrate transport direction is the X direction, a direction orthogonal to the X direction with the X direction is the Y direction, a direction orthogonal to the XY plane is the Z direction, and a direction in the horizontal plane rotating about the Z direction is the θ direction Define. The electronic component mounting apparatus 1 has a function of applying a negative pressure to the suction holes of the nozzle, holding the electronic component by vacuum suction, and mounting the electronic component on the substrate. In FIG. 1, a substrate transfer mechanism 2 provided with a pair of transfer conveyors extending in the X direction is disposed at the central portion of the base 1a. The substrate transfer mechanism 2 receives and transfers the substrate 3 to be mounted of components from the upstream side device, and positions and holds the substrate 3 at a mounting work position by the component mounting mechanism described below.

  A component supply unit 4 is disposed on both sides of the substrate transfer mechanism 2. The component supply unit 4 is configured by arranging a plurality of tape feeders 5 in parallel on the feeder table 4a. The tape feeder 5 feeds an electronic component to be mounted to a take-out position by the mounting head 8 of the component mounting mechanism by pitch-feeding a carrier tape containing the electronic component mounted on the substrate 3.

  Next, the component mounting mechanism will be described. At the end of the base 1a in the X direction, a Y-axis beam 6 provided with a linear drive mechanism is disposed, and in the Y-axis beam 6, an X-axis beam 7 provided with a linear drive mechanism is moved in the Y direction. It is mounted freely. A plate member 9 is attached to the X-axis beam 7 so as to be movable in the X direction, and a mounting head 8 is attached to the plate member 9 via a holding frame 10.

  The mounting head 8 has a function of picking up and holding the electronic component P (see FIG. 4) mounted on the substrate 3 from the component supply unit 4 by the nozzle 20 (see FIGS. 2 and 4). As the nozzle 20, a suction nozzle is used which holds the electronic component P by applying a negative pressure generated by a negative pressure generation source to a suction hole opened at a tip end. The mounting head 8 moves horizontally in the X and Y directions by driving the Y-axis beam 6 and the X-axis beam 7, and the substrate 3 holds the electronic component P held by the nozzle 20 positioned and held by the substrate conveyance mechanism 2. Attach to

  Next, the structure of the mounting head 8 will be described with reference to FIGS. 2 and 3. In FIG. 2, the mounting head 8 has a structure in which the side surface and the top surface are covered by the holding frame 10 and a cover 8 a fixed to the holding frame 10. At a lower portion of the holding frame 10, a rotor holding portion 11 is provided to extend in the horizontal direction. In the rotor holding portion 11, a cylindrical main shaft holding portion 12 which is a rotor is rotatably held with a rotation axis CL in the Z direction as an axial center via a bearing 11a (see FIG. 3).

  A plurality of main shafts 15 are held by the elevating mechanism 25 so as to be able to move up and down in a concentric arrangement around the rotation axis CL. The main shaft 15 has a nozzle holder 19 at its lower end for holding the nozzle 20 detachably. In the present embodiment, the main shaft 15 is divided into a first shaft 17 (main shaft upper portion) connected to an elevating mechanism 25 for moving the main shaft holding portion 12 up and down, and a second shaft 18 (main shaft lower portion) . The second shaft 18 is configured to include the nozzle holder 19 and a portion held by the main shaft holding portion 12. The 1st shaft 17 and the 2nd shaft 18 are connected via the shaft connection part 16 provided in the lower end part of the 1st shaft 17 (refer FIG. 11, FIG. 12).

  On an upper surface of the main shaft holding portion 12, a holding body driven gear 13 whose axis is the rotation axis CL is fixed, and an index drive motor 14 is disposed above the rotor holding portion 11. An index drive gear 14 a that meshes with the holder driven gear 13 is attached to the index drive motor 14. By driving the index drive motor 14, the holder driven gear 13 is driven through the index drive gear 14a, whereby the main shaft holder 12 is index rotated with the holder driven gear 13 (arrow a).

  In FIG. 2, at the upper part of the holding frame 10, a cam holding portion 21 for fixing the cylindrical cam 22 is provided so as to extend in the horizontal direction. Guide grooves 22 a are provided on the outer peripheral surface of the cylindrical cam 22. The guide groove 22 a is high on the side opposite to the holding frame 10 and is provided so as to be gradually lowered as the holding frame 10 is approached. The cam follower 23 attached to the first shaft 17 of each main shaft 15 is attached to the cylindrical cam 22 so as to be movable along the guide groove 22a. When the main shaft holding portion 12 is index-rotated, the main shaft 15 moves up and down along the guide groove 22a of the cylindrical cam 22 while rotating in the horizontal direction accordingly. The cylindrical cam 22 is partially cut off at a position where the guide groove 22a is lowest, and the guide groove 22a is broken at the cut portion.

  A lifting mechanism 25 is disposed between the holding frame 10 and the cylindrical cam 22. The lifting mechanism 25 includes a screw shaft 24a extending in the Z direction, a lifting motor 24 for rotating the screw shaft 24a, and a nut 24b screwed on the screw shaft 24a. The nut 24b is provided with a cam follower holder 24c which can move up and down along the cut-off portion of the cylindrical cam 22. The cam follower holder 24 c is raised and lowered together with the nut 24 b by the drive of the raising and lowering motor 24. The cam follower holder 24c has a shape that complements the guide groove 22a interrupted at the cut portion.

  The cam follower 23 which has moved along the guide groove 22a is separated from the guide groove 22a at this position, and is transferred to and held by the cam follower holder 24c which stands by at the same height position as the guide groove 22a. When the lift motor 24 is driven in this state, the cam follower 24c and the cam follower 23 move up and down together with the cam follower 23 (arrow b). As shown in FIG. 3, a substantially L-shaped joint portion 17a is rotatably mounted on the upper end portion of the first shaft 17 in the θ direction, and the cam follower 23 has an axis in the horizontal direction in the joint portion 17a. It is attached with the rotation axis of the heart facing outward. With this configuration, when the cam follower 23 moves up and down, the first shaft 17 connected via the joint portion 17a moves up and down, and accordingly the lower end portion of the second shaft 18 connected to the first shaft 17 via the shaft connecting portion 16 The nozzle 20 held by the nozzle holder 19 moves up and down (arrow c).

  That is, the position of the main shaft 15 at which the cam follower holder 24 c holds the cam follower 23 is for the main shaft 15 to pick up the electronic component P by the nozzle 20 by suction and to mount the held electronic component P on the substrate 3. The elevator position M is for raising and lowering. The rotor holding unit 11 is provided with a component recognition unit 26 for imaging the electronic component P held by the nozzle 20 from the lower side. The component recognition unit 26 holds the nozzle 20 at the lower end of the main shaft 15 held by the main shaft holding unit 12 at the timing at which the main shaft holding unit 12 positions the component recognition position R by index rotation. It has a function of imaging the state of the electronic component P from below.

  That is, the component recognition unit 26 has mirrors 26b disposed below the component recognition position R and below the camera 26a. By guiding the imaging light of the electronic component P held by the nozzle 20 located at the component recognition position R to the camera 26a by these mirrors 26b, an image of the electronic component P held by the nozzle 20 is acquired, and these are acquired By recognizing the image, the identification of the electronic component P and the misregistration state are recognized. When mounting the electronic component P on the substrate 3, the mounting position correction of the position in the θ direction of the main shaft 15 in the mounting head 8 and the XY position by the component mounting mechanism in consideration of the recognition result of the electronic component P by the component recognition unit 26 Is done.

  Next, with reference to FIG. 3, the configuration of the rotational drive system of the main shaft 15 and the suction / exhaust system in the mounting head 8 will be described. The main shaft 15 shown in the present embodiment has a cam follower 23, a joint 17a, a nozzle rotating gear 37, a first shaft 17 having a shaft connecting portion 16 at its lower end, and a second holder 17 having a nozzle holder 19 at its lower end. The shaft 18 is connected via the shaft connecting portion 16.

  As shown in FIG. 3, the second shaft 18 of the main shaft 15 is inserted through a through hole 30 provided vertically through the main shaft holding portion 12. The inner diameter of the through hole 30 is set larger than the outer diameter of the second shaft 18, and in the state where the second shaft 18 is inserted through the through hole 30, a void 30a is formed inside the through hole 30. Bearing portions 31 are attached to upper and lower end portions of each through hole 30, and the second shaft 18 is slidably and airtightly fitted to the bearing portions 31. Accordingly, the main shaft 15 can be moved up and down and rotated about its axis in a state in which the gap 30a is sealed from the outside.

  In FIG. 3, the upper surface of the main shaft holding portion 12 is provided with a mounting hole 12 a centered on the rotation axis CL of the main shaft holding portion 12. The cylindrical rotary body 35 penetrating the cylindrical cam 22 up and down is rotatably disposed with respect to the main shaft holding portion 12 by inserting the tip portion 35a into the mounting hole 12a via the bearing 35b. .

  In the vicinity of the upper end portion of the rotating body 35, a θ rotation driven gear 28 whose axis is the rotation axis CL is fixed. Above the cylindrical cam 22 is disposed a θ rotation motor 27 mounted with a θ rotation drive gear 27 a meshing with the θ rotation driven gear 28. The θ rotation driven gear 28 is rotated in the θ direction via the θ rotation drive gear 27 a by the drive of the θ rotation motor 27. Thereby, the rotary body 35 rotates in the θ direction together with the θ rotation driven gear 28 (arrow d).

  A nozzle drive gear 36 elongated in the vertical direction is coupled between the main shaft holding portion 12 and the cylindrical cam 22 in the rotary body 35 in correspondence with the elevating stroke of the main shaft 15. A nozzle rotation gear 37 is coupled to each main shaft 15 at a position engaging with the nozzle drive gear 36. The respective main shafts 15 simultaneously rotate in the θ direction through the nozzle rotation gear 37 by the drive of the nozzle drive gear 36 (arrow e). As described above, the main shaft 15 is rotated in the θ direction by the drive of the θ rotation motor 27, whereby the nozzle 20 held by the nozzle holder 19 at the lower end of the second shaft 18 is also rotated in the θ direction (arrow f).

  Next, the suction and exhaust system of the mounting head 8 will be described. In FIG. 3, a shaft bore 18 a whose lower end portion communicates with the nozzle 20 is provided inside the second shaft 18. The shaft inner hole 18a communicates with the nozzle flow path 20g (see FIG. 6) provided in the nozzle 20 via the air hole 40a provided in the nozzle holder 19 and the filter 62. Above the shaft inner hole 18a, an opening 18b opened in the outer peripheral surface of the second shaft 18 at a position between the upper and lower two bearing portions 31 and communicating with the air gap 30a is provided. The opening 18 b is located within the range of the gap 30 a sandwiched between the upper and lower two bearings 31 even when the main shaft 15 moves up and down.

  Inside the main shaft holding portion 12, a common flow passage 12b opened in the upper surface of the mounting hole 12a provided at the upper center of the main shaft holding portion 12 is provided in the vertical direction along the rotation axis CL. The common flow passage 12b communicates with a rotating internal hole 35c provided inside the rotating body 35 fitted into the mounting hole 12a. The rotating internal hole 35 c communicates with the negative pressure generation source 33 via a pipe 29 connected to the upper end of the rotating body 35. By operating the negative pressure generation source 33, it is possible to suction the inside of the common flow passage 12b via the internal rotation hole 35c to apply a negative pressure. Therefore, the common flow passage 12 b is a negative pressure side flow passage that applies a negative pressure to the nozzle 20.

  The common flow passage 12 b is in communication with the void portion 30 a of each through hole 30 via a flow passage switching portion 32 provided inside the main shaft holding portion 12. The flow path switching unit 32 is a nozzle-side flow path communicating with the nozzle 20, that is, a nozzle flow path 20g of the nozzle 20 communicating with the cavity 30a and further communicating with the opening 18b, the shaft inner hole 18a and the nozzle holder 19. It has a function to switch the connection destination. The common channel 12b which is a negative pressure side channel for applying negative pressure to the nozzle 20 as the connection destination of the nozzle 20 by the connection destination switching function, and the positive pressure side channel for applying positive pressure to the nozzle 20 Select either (not shown) to switch. By switching the flow path in this manner, it is possible to select and execute suction holding of the electronic component P by the nozzle 20 by the negative pressure and separation of the held electronic component P by the positive pressure.

  Next, with reference to FIGS. 4 to 10, the configuration and function of the nozzle holder 19 provided at the lower end portion of the second shaft 18 constituting the main shaft 15 will be described. As shown in FIG. 4, the nozzle holder 19 provided at the lower end of the second shaft 18 urges and fixes the holder cylinder 40, the clamp lever 50 and the clamp lever 50 against the holder cylinder 40. The fulcrum spring 58 and the clamp spring 59 are provided. The lower end of the nozzle holder 19 is a nozzle receiving portion 40b (see also FIGS. 7 and 8) of the holder cylindrical portion 40, and in a state where the nozzle 20 is attached to and held by the nozzle holder 19, the flange portion of the nozzle 20 The upper surface of 20b abuts on the nozzle receiving portion 40b. Then, by applying a negative pressure to the nozzle 20 in this state, the electronic component P is held on the suction surface of the tip portion 20a.

  Here, the configuration of the nozzle 20 held by the nozzle holder 19 will be described with reference to FIG. In the nozzle holder 19, the nozzle 20 has a tip 20a provided with a suction hole 20f for holding the electronic component P by suction, and a mounting portion 20c which is a portion detachably mounted on the nozzle holder 19; At the time of mounting on the nozzle holder 19, a flange portion 20b which abuts on the nozzle receiving portion 40b extends laterally.

  Further, the mounting portion 20c is provided with a large diameter portion 20d provided at the upper end, and an engaged portion 20e for engaging the engaging portion 57 of the clamp lever 50 to fix the nozzle 20. It is done. Inside the nozzle 20, a nozzle flow passage 20g (first suction passage) penetrating from the tip end portion 20a to the mounting portion 20c is provided in communication with the suction hole 20f opened in the tip end portion 20a.

  And the nozzle 20 hold | maintains the electronic component P by vacuum suction at the front-end | tip part 20a by the negative pressure introduced into the nozzle flow path 20g. A cartridge 60 having a filter holder 61 for holding therein a filter 62 for filtering the air sucked from the nozzle 20 is accommodated above the mounting portion 20 c in the nozzle holder 19.

  Next, the shapes and functions of the holder cylinder 40 and the clamp lever 50 will be described with reference to FIGS. 7 and 8. As shown in FIG. 7, the holder cylinder portion 40 is a cylindrical member having an insertion hole 41 into which the mounting portion 20 c (see FIG. 6) provided in the nozzle 20 is inserted. As shown in FIGS. 7 and 8 (cross section AA in FIG. 7), an opening 41a communicating with the insertion hole 41 is formed on one side surface (upper surface in FIG. 7) of the insertion hole 41.

  Three notches of a first notch 42, a second notch 43, and a third notch 44 are provided from the upper side on the side surface of the range in which the opening 41a is formed in the holder cylinder 40 It is formed. These notches have a shape in which the cylindrical portion of the holder cylindrical portion 40 is partially cut away in a plane parallel to the opening 41 a. Further, a fulcrum spring holding portion 46 and a clamp spring holding portion 47 are formed at positions where the second notch portion 43 and the third notch portion 44 are formed. One clamp lever 50 having a shape shown in FIG. 7 is fitted into the opening 41a.

  The clamp lever 50 has a function of locking the mounting portion 20c inserted into the insertion hole 41 by an engagement portion 57 provided on the operation portion 52 described below. That is, in the present embodiment, the engagement portion 57 of one clamp lever 50 is engaged with the mounting portion 20c of the nozzle 20 inserted into the insertion hole 41 via the opening 41a. Thus, the nozzle holder 19 can be miniaturized by locking the nozzle 20 with the single clamp lever 50.

  The clamp lever 50 has a circumferential surface having substantially the same curvature as the outer periphery of the portion of the holder cylinder 40 where the opening 41a is formed on the upper surface, and the opening 41a, the first notch 42, and the second It is a deformed member having a planar shape that can be inserted into the notch 43 and the third notch 44. The detailed shape and function of the clamp lever 50 will be described. The central portion of the clamp lever 50 is a fulcrum 51. The fulcrum part 51 is provided with an overhanging part 51a having a shape that can be inserted into the second notch 43 and extended on both sides, and the lower surface of the overhanging part 51a is in contact with the fulcrum support 45 and the clamp lever An abutment fulcrum 56 is provided as a center when swinging 50.

  The position extending downward from the fulcrum portion 51 is an action portion 52. The action part 52 is provided with a projecting part 52 a having a shape that can be inserted into the third notch 44 so as to extend on both sides. Further, on the lower surface of the acting portion 52, an engaging portion 57 shaped to engage with the engaged portion 20e of the mounted portion 20c inserted into the insertion hole 41 is provided (see also FIG. 6). Further, a position extending upward from the fulcrum portion 51 is the operation portion 53, and the operation portion 53 is provided with a projecting portion 53a having a shape that can be inserted into the first notch portion 42 so as to extend on both sides There is.

  That is, as shown in the above configuration, the clamp lever 50 has a fulcrum portion 51, an action portion 52 extending downward from the fulcrum portion 51, and an operation portion 53 extending upward from the fulcrum portion 51. ing. As described above, three notches of the first notch 42, the second notch 43, and the third notch 44 are formed on the side surface of the holder cylinder 40, and the clamp At least a part of the lever 50 is arranged inside these notches. As described above, the external shape of the nozzle holder 19 can be miniaturized by arranging a part of the clamp lever 50 in the notch formed in the holder cylindrical portion 40.

  Between the fulcrum portion 51 and the operation portion 53, a narrow groove-shaped fulcrum portion side groove 54 is provided, and between the operation portion 52 and the fulcrum portion 51, a wide groove-shaped operation portion side groove 55 is provided. It is provided. As shown in FIGS. 4 and 5, when attaching the clamp lever 50 to the holder cylinder portion 40, first, the projecting portions 53a, 51a, 52a are respectively formed into the first notch 42 and the second notch 43, The third notch 44 is inserted. At this time, the abutment fulcrum 56 provided on the lower surface of the overhanging portion 51 a abuts on the fulcrum supporting portion 45 (see FIG. 7) which is a notch surface of the second notch 43. That is, the holder cylinder 40 is provided with a fulcrum support 45 that supports the contact fulcrum 56 in the second notch 43. By using the second notch 43 provided in the holder cylinder 40 as the fulcrum support 45 for supporting the clamp lever 50 as described above, the outer shape of the nozzle holder 19 can be miniaturized.

  A fulcrum spring 58 using a coil spring is mounted on the outer periphery of the fulcrum portion side groove 54 and the fulcrum spring holding portion 46 so as to spirally wind around them. The fulcrum spring 58 is a second elastic member that biases the abutment fulcrum 56 of the fulcrum 51 of the clamp lever 50 to the fulcrum support 45. As a result, the clamp lever 50 is maintained in a state in which the contact fulcrum 56 of the fulcrum 51 is in contact with the fulcrum support 45, and is held by the fulcrum support 45 so as to be pivotable about the contact fulcrum 56. It becomes a state.

  With such a configuration, the following function is realized by the clamp lever 50 swinging about the contact fulcrum 56 of the fulcrum 51. That is, by displacing the action part 52 side to the inside of the holder cylinder part 40, the engaging part 57 formed in the action part 52 is advanced into the insertion hole 41 which is the inside of the holder cylinder part 40. There is. On the other hand, when the operation part 53 side is displaced to the inside of the holder cylinder part 40, the action part 52 opens outward, and the locking of the mounted part 20c inserted in the insertion hole 41 of the holder cylinder part 40 is released. As described later, the cartridge 60 can be taken in and out of the insertion hole 41 through the inlet 41b (see FIG. 7) (see FIG. 10).

  That is, in the clamp lever 50 configured as described above, the engaging portion 57 is formed to engage with the mounting portion 20c of the nozzle 20 inserted into the insertion hole 41 in a state of closing the entrance 41b of the insertion hole 41 through the opening 41a. It is done. As a result, the engaging function of engaging with the nozzle 20 and fixingly mounting it on the nozzle holder 19 and closing the opening 41a of the insertion hole 41 by the engaging portion 57 when the nozzle 20 is not present prevents the cartridge 60 from coming off. It has a retaining function to prevent it. In the present embodiment, the nozzle holder 19 has only one clamp lever 50 having such a function, and the locking of the nozzle 20 and the retention prevention of the cartridge 60 are performed by only the single clamp lever 50. It is realized that the nozzle holder 19 can be made smaller and smaller.

  In the state shown in FIG. 5, that is, in the state in which the nozzle 20 is inserted into and held by the holder cylinder 40, the nozzle receiving portion 40b of the holder cylinder 40 is positioned below the lower end 50a of the clamp lever 50. It has become. Thereby, the lower end portion of the holder cylinder portion 40 functions as a bumper protecting the clamp lever 50, and the damage due to the nozzle or other foreign matter colliding with the lower end portion of the clamp lever 50 can be prevented.

  As in the configuration according to the present embodiment, in the configuration in which the clamp lever 50 is held by an elastic member such as the fulcrum spring 58 or the clamp spring 59, the shift of the fulcrum due to the application of an unexpected external force, the drop of the clamp lever 50, etc. It is possible to prevent the Further, the nozzle receiving portion 40b of the holder cylindrical portion 40 serves as a nozzle receiving member that abuts on the flange portion 20b of the nozzle 20 mounted on the nozzle holder 19, thereby preventing rattling of the nozzle 20 mounted on the nozzle holder 19. It is possible to

  A clamp spring 59 using a compression coil spring is mounted around the clamp spring holding portion 47 of the holder cylindrical portion 40 and the outer periphery of the action portion side groove 55 of the clamp lever 50 by spirally winding around them. The clamp spring 59 is a first elastic member that biases the engaging portion 57 of the fulcrum 51 to the mounting portion 20 c inserted into the insertion hole 41. At this time, the clamp spring 59 is set so that the clamp spring 59 orbits and winds the action-part-side groove 55 of the clamp lever 50 and the clamp spring holding part 47 of the holder cylindrical part 40. In this state, as shown in FIG. 5, the clamp lever 50 and a part of the holder cylinder portion 40 are inserted into the inner diameter space 59a of the clamp spring 59, and the clamp spring 59 The nozzle holder 19 is mounted in contact with the nozzle holder 40.

  As described above, in the embodiment in which the clamp lever 50 is held on the holder cylindrical portion 40 by the clamp spring 59, in the present embodiment, the action portion side groove 55 is set narrower than the clamp spring holding portion 47. The action portion groove 55 on the clamp lever 50 side is compressed in the vertical direction more than other portions, that is, the clamp spring holding portion 47 side of the holder cylindrical portion 40. Thus, in the clamp spring 59 using the compression coil spring having a configuration in which a plurality of coil rings are wound, the plurality of coil rings 59 * located on the lower side are between the clamp spring holding portion 47 and the action portion groove 55 It is wound in an inclined state.

  As a result, tension (arrow g) that does not occur in the normal use of the compression coil spring acts on the coil ring 59 * in the inclined state. Then, by this tension, the fulcrum portion 51 provided with the action portion side groove 55 is locked in the inward direction of the holder cylindrical portion 40, that is, in the direction to press the engaging portion 57 against the mounting portion 20c attached to the insertion hole 41. Force works. As a result, with a compact configuration using a small-sized clamp spring 59, a sufficient force can be applied to the clamp lever 50 in the closing direction, and the mounting portion 20c can be stably locked. Is possible.

  As shown in FIG. 8, a vent 40a for introducing a negative pressure to the insertion hole 41 is provided at the upper end of the insertion hole 41 provided in the holder cylinder 40, and the vent 40a is shown in FIG. It is connected to a negative pressure source 33 via a rotating internal hole 35c shown. That is, the vent hole 40a constitutes a second suction passage connected to the negative pressure generation source 33, and in the nozzle holder 19 having the above configuration, the insertion hole 41 formed in communication with the end of the second suction passage The mounting portion 20 c of the nozzle 20 is inserted and the nozzle 20 is detachably held. Further, the insertion hole 41 has a function of inserting and storing a cartridge 60 having a filter 62 for filtering the air sucked from the nozzle 20.

  The lower side of the insertion hole 41 is an open inlet 41b, which serves as an inlet for inserting the cartridge 60 (see FIG. 6) stored in the nozzle holder 19 and the mounting portion 20c of the nozzle 20. ing. Further, at the back of the insertion hole 41, there is provided a stopper 41c which is a position regulating surface which abuts on the upper end of the cartridge 60 inserted into the insertion hole 41 to regulate the position.

  Next, referring to FIGS. 6, 9, and 10, the electronic component mounting apparatus 1 having the nozzle holder 19 having the above-described configuration is used and mounted on the nozzle holder 19 in a state of being inserted into the holder cylindrical portion 40. The cartridge 60 and the mounting and demounting structure of the cartridge 60 will be described.

  FIG. 6 shows a state in which the cartridge 60 is accommodated in the nozzle holder 19 and the nozzle 20 is held by the nozzle holder 19. First, the configuration of the cartridge 60 will be described. The cartridge 60 includes a cylindrical filter holder 61 inserted into the insertion hole 41, a filter 62 disposed in the internal space 61a of the filter holder 61, and an annular member disposed at one end 61b of the filter holder 61. A packing 63, a ventilation hole 61e provided inside the other end 61c of the filter holder 61, and a pad portion 64 arranged at the other end 61c are provided.

  The filter holder 61 has an external dimension that can be inserted into the insertion hole 41 formed in the holder cylinder 40, and has an internal space 61a penetrating from one end 61b to the other end 61c. The filter 62 is disposed in the internal space 61 a and has a function of filtering the air sucked from the nozzle flow path 20 g which is the first suction path. The packing 63 airtightly connects the ventilation hole 40 a, which is the second suction passage, and the internal space 61 a by contacting the stopper 41 c provided at the back of the insertion hole 41. The pad portion 64 airtightly connects the nozzle flow path 20 g and the internal space 61 a by contacting the large diameter portion 20 d of the mounting portion 20 c inserted into the insertion hole 41.

  As described above, the cartridge 60 can be easily attached to and detached from the nozzle holder 19 only by inserting the cartridge 60 integrated with the filter 62, the packing 63, and the pad portion 64 into the insertion hole 41. Sex has been greatly improved. Further, by merely interposing the packing 63 and the pad portion 64 in the upper and lower portions of the cartridge 60, not only the airtightness is ensured, but also the effect of reducing the impact when attaching and detaching the nozzle 20 is obtained.

  Here, the structure of the filter 62 mounted in the internal space 61 a in the filter holder 61 will be described. The filter 62 projects from the base 62a to the other end 61c of the filter holder 61 with a gap from the base 62a contacting the inner wall 61d of the filter holder 61 on the inner space 61a side and the inner wall 61d. It has composition which has 62b and crevice 62c opened to base 62a.

  By setting the mounting structure of the filter 62 to the filter holder 61 as such a simple method, a special structure for fixing the filter 62 to the filter holder 61 is not required, and a cartridge having a small and simple structure can be obtained. It has been realized. Further, by making the cross-sectional shape of the filtration part 62b U-shaped and not making contact with the inner wall 61d of the filter holder 61, a large filtration area can be secured with a small diameter, and the filter 62 can be miniaturized and filtered. The improvement of performance can be made compatible.

  Further, when the filter 62 is attached to the filter holder 61, the base 62a protrudes from the internal space 61a of the filter holder 61, and the packing 63 is held by the protrusion. As a result, there is no need to provide a special structure for fixing the packing 63 to the filter holder 61, and the packing 63 can be attached simply by holding the annular packing 63 on the outer periphery of the cylindrical base 62a. it can.

  FIG. 9 shows a state in which the nozzle 20 is removed from the state shown in FIG. The removal of the nozzle 20 is performed by applying a force to the nozzle 20 in the pulling direction (arrow h) by a manual operation or a nozzle changer or the like. That is, the engaging portion 57 of the action portion 52 is disengaged from the engaged portion 20e against the biasing force of the clamp spring 59 by this pulling force, whereby the locking of the mounted portion 20c is released, and the nozzle 20 Can be removed from the nozzle holder 19. When the nozzle 20 is held by the nozzle holder 19, an operation of inserting and pushing the mounting portion 20 c into the insertion hole 41 is performed. As a result, the engagement portion 57 of the action portion 52 is fitted to the engaged portion 20e, and the engagement of the mounted portion 20c is performed.

  As described above, when the nozzle 20 is removed from the nozzle holder 19, the locking object is not present at the position corresponding to the fulcrum 51 in the insertion hole 41 inside the holder cylinder 40. In the present embodiment, since the clamp lever 50 is swingable about the contact fulcrum 56 of the fulcrum 51, the action portion 52 of the clamp lever 50 is moved toward the insertion hole 41 by the biasing force of the fulcrum spring 58. Displace (arrow i). The engaging portion 57 of the displaced operating portion 52 advances into the insertion hole 41 to close the inlet 41 b, thereby preventing the cartridge 60 contained therein from coming off. With such a configuration, the clamp lever 50 can also serve as a retainer for the cartridge 60, and the nozzle holder 19 can be miniaturized.

  FIG. 10 shows a state in which the cartridge 60 is detached from the nozzle holder 19 with the nozzle 20 removed from the nozzle holder 19. In this case, the operation portion 53 side of the clamp lever 50 is manually displaced to the inside of the holder cylinder portion 40 (arrow j). As a result, the clamp lever 50 swings about the contact fulcrum 56 (see FIG. 4) of the fulcrum 51 by a predetermined amount of rotation, and the action part 52 is displaced in the direction to open outward (arrow k). Thereby, the engaging portion 57 of the action portion 52 can be withdrawn from the inside of the insertion hole 41, and the cartridge 60 can be taken in and out of the insertion hole 41 (arrow m) through the inlet 41b.

  By enabling the operations shown in FIGS. 9 and 10, the dropout of the cartridge 60 is prevented even when only the cartridge 60 is stored in the nozzle holder 19 as during the automatic replacement of the nozzle 20. Ru. When necessary, the cartridge 60 can be taken out or replaced from the insertion hole 41 of the nozzle holder 19 only by operating the clamp lever 50. In the present embodiment, since the filter 62 is simply held to hold the cartridge 60 inside the cylindrical filter holder 61, the cartridge 60 can be easily taken in and out of the insertion hole 41 of the nozzle holder 19 It can be carried out.

  Next, with reference to FIGS. 11-14, the connection structure of the 1st shaft 17 and the 2nd shaft 18 which comprise the main shaft 15 is demonstrated. 11, an insertion end 18c (see FIG. 12) provided at the upper end of the first shaft 17 is inserted into the shaft connection 16 provided at the lower end of the first shaft 17, and the shaft connection 16 is obtained. Shows a state in which the second shaft 18 is held.

  As shown in FIG. 12, an insertion end 18 c having a shape obtained by D-cutting one surface is provided in a predetermined range of the upper end of the second shaft 18. In the lower part of the insertion end 18c, a groove 18d is linearly formed in a direction orthogonal to the axial direction of the main shaft 15. The shaft connecting portion 16 provided at the lower end portion of the first shaft 17 is configured to have a shaft holder cylindrical portion 70, a shaft clamp lever 80 and a clamp spring 89 (FIG. 11). The clamp spring 89 has a function as an elastic member that biases the shaft clamp lever 80 against the groove 18 d of the insertion end 18 c attached to the shaft holder cylindrical portion 70.

  The shaft holder cylindrical portion 70 has a tubular shape having an insertion hole 71 into which the insertion end 18c of the second shaft 18 is inserted, and an opening 71a communicating with the insertion hole 71 is formed on one side surface thereof. In the side surface of the substantially central portion of the opening 71a in the shaft holder cylindrical portion 70, a cutout 72 having a shape in which the cylindrical portion of the shaft holder cylindrical portion 70 is partially cut away in a plane parallel to the opening 71a is formed There is. Further, a fulcrum spring holding portion 75 is formed at the position where the notch portion 72 is formed.

  One shaft clamp lever 80 having a shape shown in FIG. 12 is fitted in the opening 71a, and the shaft clamp lever 80 is provided with an insertion end 18c inserted into the insertion hole 71 in the action portion 82 described below It has a function of locking by the engaged portion 87. That is, in the present embodiment, the engaging portion 87 of one shaft clamp lever 80 is engaged with the groove 18d of the insertion end 18c inserted into the insertion hole 71 through the opening 71a. As described above, the configuration in which the insertion end 18 c is locked by the single shaft clamp lever 80 realizes miniaturization of the nozzle holder 19 and, at the same time, only one shaft clamp lever 80 is operated. The ability to connect and remove the second shaft 18 from the shaft 17 improves the operability at the time of operation.

  The detailed shape and function of the shaft clamp lever 80 will be described. A central portion of the shaft clamp lever 80 is a fulcrum portion 81. The fulcrum 81 is provided with an overhang 81a extending to both sides so as to fit into the notch 72. The lower surface of the overhang 81a abuts against the fulcrum support 74 to shake the shaft clamp lever 80. An abutment fulcrum 86 is provided at the center of movement. The position extending downward from the fulcrum portion 81 is an action portion 82. The lower surface of the action portion 82 is provided with an engaging portion 87 shaped to engage with the groove 18d of the insertion end 18c inserted into the insertion hole 71 on the lower surface (see also FIG. 13). Further, a position extending upward from the fulcrum portion 81 is an operation portion 83.

  That is, as shown in the above configuration, the shaft clamp lever 80 has a configuration having a fulcrum portion 81, an action portion 82 extending downward from the fulcrum portion 81, and an operation portion 83 extending upward from the fulcrum portion 81. It has become. As described above, the notch portion 72 is formed on the side surface of the shaft holder cylindrical portion 70, and at least a portion of the shaft clamp lever 80 is disposed inside the notch portion 72. As described above, by disposing a part of the shaft clamp lever 80 in the cutout portion formed in the shaft holder cylindrical portion 70, it is possible to miniaturize the outer shape of the shaft connecting portion 16.

  The fulcrum part 81 is provided with a narrow groove-shaped fulcrum part-side groove 84, and the action part 82 is provided with a wide groove-shaped action part-side groove 85. As shown in FIG. 11, when attaching the shaft holder cylindrical portion 70 to the shaft clamp lever 80, first, the projecting portion 81a is fitted into the notch portion 72. At this time, the abutment fulcrum 86 provided on the lower surface of the overhanging part 81a abuts on a fulcrum supporting part 74 (see FIG. 12) which is a cutout surface of the cutout part 72. That is, the shaft holder cylindrical portion 70 is provided with a fulcrum support portion 74 for supporting the contact fulcrum 86 in the notch portion 72. By using the notched portion 72 provided in the shaft holder cylindrical portion 70 as the fulcrum support portion 74 for supporting the shaft clamp lever 80 as described above, the outer shape of the shaft connecting portion 16 can be miniaturized.

  A fulcrum spring 88 using a coil spring is mounted on the outer periphery of the fulcrum portion side groove 84 and the fulcrum spring holding portion 75 so as to spirally wind around them. The fulcrum spring 88 has a function of biasing the contact fulcrum 86 of the fulcrum portion 81 of the shaft clamp lever 80 to the fulcrum support portion 74. As a result, the shaft clamp lever 80 is maintained in a state in which the contact fulcrum 86 of the fulcrum 81 is in contact with the fulcrum support 74, and is held movably about the contact fulcrum 86 by the fulcrum support 74. It will be

  With such a configuration, the following function is realized by the shaft clamp lever 80 swinging about the abutment fulcrum 86 of the fulcrum 81. That is, by displacing the acting portion 82 side to the inside of the shaft holder cylindrical portion 70, the engaging portion 87 formed in the acting portion 82 is advanced into the insertion hole 71 which is the inside of the shaft holder cylindrical portion 70. It has become. On the other hand, when the operation part 83 side is displaced to the inside of the shaft holder cylindrical part 70, the action part 82 opens outward, and the locking of the insertion end 18c inserted in the insertion hole 71 of the shaft holder cylindrical part 70. , And the connection between the first shaft 17 and the second shaft 18 by the shaft connection portion 16 can be released.

  A clamp spring 89 using a compression coil spring is mounted around the clamp spring holding portion 47 of the shaft holder cylindrical portion 70 and the outer periphery of the action portion side groove 85 of the shaft clamp lever 80 by spirally winding them. There is. The clamp spring 89 is an elastic member that urges the engagement portion 87 of the action portion 82 to the groove 18 d of the insertion end 18 c inserted into the insertion hole 71. At this time, the clamp spring 89 is set so that the clamp spring 89 orbits and winds the action-part-side groove 85 of the shaft clamp lever 80 and the clamp spring holding part 76 of the shaft holder cylindrical part 70. In this state, as shown in FIG. 13, the shaft clamp lever 80 and a part of the shaft holder cylindrical portion 70 are inserted into the inner diameter space 89 a of the clamp spring 89, and the clamp spring 89 The shaft connecting portion 16 is mounted in a state of being in contact with the shaft holder cylindrical portion 70.

  As described above, in the embodiment in which the shaft clamp lever 80 is held on the shaft holder cylindrical portion 70 by the clamp spring 89, in the present embodiment, the action portion side groove 85 is set narrower than the clamp spring holding portion 76. 89 is compressed in the vertical direction more than other portions, that is, the clamp spring holding portion 76 side of the shaft holder cylindrical portion 70 by the action portion side groove 85 on the shaft clamp lever 80 side. Thus, in the clamp spring 89 having a configuration in which a plurality of coil rings are wound, the plurality of coil rings 89 * (see FIG. 11) located on the lower side are between the action portion groove 85 and the clamp spring holding portion 76. It is wound in an inclined state.

  As a result, tension (arrow n) that does not occur when the compression coil spring is used normally acts on the coil ring 89 * in the inclined state. Then, the engaging portion 87 is pressed against the groove portion 18d of the insertion end portion 18c inserted into the insertion hole 71 in the inward direction of the shaft holder cylindrical portion 70, that is, the action portion 82 provided with the action portion groove 85 by this tension. A directional locking force acts. Thus, the compact configuration using the small-sized clamp spring 89 can apply a sufficient force in the closing direction to the shaft clamp lever 80, and stabilize the groove 18d of the insertion end 18c. By locking, it is possible to prevent problems such as generation of vibration in the shaft connection portion 16.

  FIG. 13 shows a state in which the first shaft 17 and the second shaft 18 are connected via the shaft connecting portion 16 of the above-described configuration provided on the first shaft 17. That is, the insertion end 18c of the second shaft 18 is inserted from below into the insertion hole 71 provided in the shaft holder cylindrical portion 70, and the receiving end 70b of the shaft holder cylindrical portion 70 contacts the second shaft 18 18e (see also FIG. 12) is pushed in until it abuts. In this operation, the action portion 82 is first spread by the end of the insertion end 18 c against the biasing force of the clamp spring 89. Next, when the groove 18 d provided in the insertion end 18 c reaches the position of the engaging portion 87, the engaging portion 87 engages with the groove 18 d and is locked by the biasing force of the clamp spring 89.

  FIG. 14 shows an operation of removing the second shaft 18 from the connected state shown in FIG. That is, in this removal operation, first, the operation portion 83 of the shaft clamp lever 80 is pressed with fingers or the like to push the insertion hole 71 inward (arrow o). By this operation, the shaft clamp lever 80 pivots about the abutment fulcrum 86 (FIG. 12) of the fulcrum 81, and the action portion 82 is displaced in the direction of opening outward against the biasing force of the clamp spring 89. (Arrow p). As a result, the engagement state of the engaging portion 87 with the groove 18 d is released, and the operation of pulling out the insertion end 18 c from the insertion hole 71 (arrow q) becomes possible.

  In this removal operation, the second shaft 18 can be taken out only by a simple pressing operation for one shaft clamp lever 80. Further, in the main shaft 15, since there is no part or the like that becomes an obstacle to the operation between the shaft connecting portion 16 and the main shaft holding portion 12 (see FIG. 2) located below the first shaft 17, It is possible to carry out work of inserting and removing the shaft 17 and the second shaft 18 with good workability.

  As described above, in the electronic component mounting apparatus according to the present embodiment, the nozzle holder 19 for detachably holding the nozzle 20 at the lower end portion of the main shaft 15 is inserted into which the mounting portion 20 c of the nozzle 20 is inserted. A cylindrical holder having a hole 41, and a holder cylindrical portion 40 having an opening 41a communicating with the insertion hole 41 on one side, and a mounting portion of the nozzle 20 inserted into the insertion hole 41 through the opening 41a. 20c: a single clamp lever 50 having an engaging portion 57 engaged with the cam 20c; and a clamp spring 59 urging the engaging portion 57 toward the mounting portion 20c of the nozzle 20 inserted into the insertion hole 41. It is As a result, in the configuration in which the nozzle 20 for holding the electronic component under negative pressure is detachably held by the nozzle holder 19, the miniaturization of the nozzle 20 and the nozzle holder 19 can be realized.

  In the electronic component mounting apparatus according to the present embodiment, in the configuration in which the cartridge 60 having the filter 62 for filtering the air sucked from the nozzle 20 is housed in the nozzle holder 19, the nozzle holder 19 is A cylindrical holder cylinder portion 40 having an insertion hole 41 for inserting and storing and a vent hole 40a for introducing a negative pressure into the insertion hole 41, and the insertion hole 41 mounted in the insertion hole 41 in a state of closing the inlet 41b. The clamp lever 50 has an engaging portion 57 engaged with the mounting portion 20c of the nozzle 20, and the clamp lever 50 moves toward the insertion hole 41 when the nozzle 20 is removed from the nozzle holder 19. The cartridge 60 is prevented from being displaced and coming off of the insertion hole 41. Thus, the nozzle holder 19 has a small size in the configuration provided with the cartridge 60 having the filter 62 for detachably holding the nozzle 20 holding the electronic component by negative pressure on the nozzle holder 19 and filtering the air sucked from the nozzle 20. As a result, the cartridge 60 can be easily stored and removed from the nozzle holder 19.

  Further, the cartridge for the electronic component mounting apparatus described in the present embodiment has an external dimension that can insert the configuration of the cartridge 60 stored in the nozzle holder 19 into the insertion hole 41 and extends from one end 61b to the other end 61c. A filter holder 61 having a penetrating internal space 61a, a filter 62 disposed in the internal space 61a for filtering the air sucked from the nozzle flow path 20g which is a first suction path, and one end of the filter holder 61 An annular packing 63 for airtightly connecting the air hole 40a, which is a second suction passage, and the internal space 61a by being disposed in the space 61b and in contact with a stopper 41c provided at the back of the insertion hole 41; The nozzle flow path 20g and the internal space are arranged by contacting the mounting portion 20c disposed at the other end 61c of the body 61 and inserted into the insertion hole 41. And 61a has a configuration that includes a pad portion 64 formed of an elastic member which hermetically connected. As a result, in the configuration provided with the cartridge 60 having the filter 62 for filtering the air sucked from the nozzle 20, the miniaturization of the nozzle holder 19 and the improvement of the filtration performance of the filter 62 and the workability at the time of attachment and detachment can be improved. .

  Furthermore, the electronic component mounting apparatus described in the present embodiment includes a main shaft 15 having a nozzle holder 19 at a lower end portion that holds the nozzle 20 detachably, and a first shaft 17 that is an upper main shaft that connects the lifting mechanism 25. The lower end portion of the first shaft 17 is provided on the second shaft 18 in a configuration divided into the second shaft 18 which is the lower portion of the main shaft including the nozzle holder 19 and the portion held by the main shaft holding portion 12 A groove 18d having a shaft connecting portion 16 for inserting and holding the insertion end 18c and linearly formed in the direction perpendicular to the axial direction of the main shaft 15 in the insertion end 18c of the second shaft 18 A shaft clamp lever 80 engaged with the groove 18d in the shaft connecting portion 16; A clamp spring 89 as an elastic member biased to d is configured. Thus, in the configuration in which the main shaft 15 having the nozzle holder 19 for holding the nozzle 20 is detachably divided vertically into two via the shaft connection portion 16, the structure of the shaft connection portion 16 can be miniaturized and simplified. The workability at the time of attachment and detachment can be improved.

  The cartridge for the electronic component mounting apparatus of the present invention has a cartridge having a filter for filtering the air drawn from the nozzle, and with the miniaturization of the nozzle holder, the filtration performance of the filter is improved and the workability at the time of attachment and detachment is improved. It is useful in the component mounting field where the electronic components are held by negative pressure and mounted on a substrate.

DESCRIPTION OF SYMBOLS 1 electronic component mounting apparatus 8 mounting head 12 main shaft holding part 15 main shaft 16 shaft connection part 17 1st shaft 18 2nd shaft 19 nozzle holder 20 nozzle 20a tip 20g nozzle flow path 20c mounting part 25 raising / lowering mechanism 40 holder cylinder 40a vent 41 insertion hole 41a opening 41c stopper 45 fulcrum support 50 clamp lever 51, 81 fulcrum 52, 82 operation part 53, 83 operation part 57 engagement part 58 fulcrum spring 59, 89 clamp spring 60 cartridge 61 filter Holding body 62 filter 63 packing 64 pad portion 70 shaft holder cylindrical portion 71 insertion hole 80 shaft clamp lever 87 engagement portion

Claims (2)

There is provided a first suction passage having a tip end and a mounting portion and penetrating from the tip to the mounting portion, and an electronic component is attached to the tip by a negative pressure introduced into the first suction path. An electron comprising a nozzle for holding and a nozzle holder for inserting the mounting portion into an insertion hole provided in communication with a second suction path connected to a negative pressure generation source to detachably hold the nozzle A cartridge for an electronic component mounting apparatus, which is used in a component mounting apparatus and mounted on the nozzle holder in a state of being inserted into the insertion hole,
A filter holder having an external dimension insertable into the insertion hole and having an internal space penetrating from one end to the other end;
A filter disposed in the inner space for filtering the air drawn from the first suction passage;
An annular packing that is disposed at the one end of the filter holder and that airtightly connects the second suction path and the internal space by abutting against a stopper provided at the back of the insertion hole;
A pad formed of an elastic member disposed at the other end of the filter holder and connecting the first suction path and the internal space in an airtight manner by contacting the mounting portion inserted into the insertion hole. and a part,
The filter has a base in contact with the inner wall at one end of the filter holder.
The cartridge for an electronic component mounting device, wherein the base of the filter protrudes from one end of the filter holder, and the packing is held by the protrusion . The filter includes a filtering portion projecting from said base portion to the other end of the filter holder in a state of spaced inner and clearance before Symbol the holding member,
The cartridge for the electronic component mounting apparatus according to claim 1, further comprising: a recess opened in the base.

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