JP4766636B2 - Bar-shaped article feeder - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a feeder that supplies, for example, a rod-shaped article such as a filter rod used for manufacturing a filter cigarette toward a consuming device.
[0002]
[Prior art]
This kind of rod-shaped article feeder includes, as disclosed in Japanese Patent Laid-Open No. 60-177109 and Japanese Patent Laid-Open No. 8-58972, a dual-drum type feeder equipped with grooved drums above and below, There is a single drum type feeder provided with only one grooved drum as disclosed in JP-A-77-147963.
[0003]
In any of these types of feeders, rod-shaped articles, that is, filter rods are taken out one by one by a grooved drum from the outlet of the hopper, and the compressed air is intermittently transferred in the subsequent transfer process. A pneumatic pressure is applied to the filter rod by jetting, the filter rod is discharged from the feeder into the pneumatic feeding pipe by this pneumatic feeding pressure, and a filter cigarette manufacturing machine, a so-called filter, is a consumption device through the pneumatic feeding pipe. I am trying to send it by air towards the attachment.
[0004]
[Problems to be solved by the invention]
By the way, in recent years, as the production speed of filter cigarettes by the filter attachment increases, even in this type of feeder, further increase in the supply speed of the filter rod is required.
To increase the speed of the feeder, it is necessary to increase both the rotational speed of the grooved drum and the discharge speed of the filter rod from the feeder. However, the high speed rotation of the grooved drum will also cause the removal groove to move before the filter rod in the hopper falls into the grooved drum takeout groove, leaving the hopper outlet empty. The filter rod is securely received by the take-out groove, that is, the filter rod cannot be stably taken out from the hopper.
[0005]
In this regard, the feeder disclosed in Japanese Patent Application Laid-Open No. 60-177109 is provided with an air hole for ejecting compressed air on one side wall of a hopper located on the rotational entry side of the grooved drum, and the groove is formed from the air hole. The compressed air flow is ejected toward the outer peripheral surface of the attached drum so that the filter rod in the hopper is forcibly dropped into the groove. However, with such a compressed air flow alone, there is a groove. Cannot cope with high-speed drum rotation.
[0006]
More specifically, in the case of the feeder described in the above publication, the lower part of one side wall of the hopper has a relatively gentle slope, for example, about 30 °. Since the filter rod is substantially supported by the lower portion of one side wall, the weight of the filter rod stacked on the upper side of the filter rod is greatly increased, and even if the compressed air flow described above is applied, the grooved drum It is considered that the flow speed of the filter rod toward the take-out groove is insufficient for high-speed rotation, and the reception of the filter rod in the take-out groove becomes unstable.
[0007]
On the other hand, even if the filter rod is received in the take-out groove, the high-speed rotation of the grooved drum makes the receiving posture of the filter rod unstable. That is, the filter rod is easily received in a state where it is inclined with respect to the groove direction of the take-out groove.
In this case, in the above-described dual drum type feeder, delivery of the filter rod between the upper and lower grooved drums becomes unstable. On the other hand, in the case of a single drum type feeder, the air feed pressure cannot be applied straight to the end face of the filter rod, so that stable discharge of the filter rod becomes impossible and the filter rod is clogged in the feeder. Easy to generate.
[0008]
Furthermore, in any type of known feeder, a non-contact type rotational support structure is adopted for the casing in order to reduce rotational resistance in the grooved drum that receives the supply of air feeding pressure. In addition, this non-contact type rotation support structure secures gaps between the casing and the three ends of the grooved drum on both sides and the outer peripheral surface. In such a rotation support structure, since the size of each gap largely depends on the processing accuracy and assembly accuracy of the parts, it is very difficult to accurately maintain each gap in a desired size. For this reason, in order to increase the discharge speed of the filter rod, when the air feeding pressure that is intermittently supplied is increased, the high pressure air feeding pressure leaks greatly through the gap. The drum generates vibrations in the radial direction and the axial direction. Such vibration of the grooved drum may cause interference between the grooved drum and the casing, and may make the rotation of the grooved drum itself impossible.
[0009]
The present invention has been made on the basis of the above-described circumstances, and its object is to provide a rod-shaped article capable of increasing the supply speed of the rod-shaped article while maintaining stable removal and discharge of the rod-shaped article from the hopper. The object is to provide an article feeder.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a hopper for storing rod-shaped articles, an upper drum that is provided to be rotatable in one direction with the outer peripheral surface closing the outlet of the hopper, and an outer peripheral surface of the upper drum. An extraction groove that is provided at equal intervals in the circumferential direction, sucks and receives the bar-shaped articles in the hopper one by one when passing through the outlet of the hopper with the rotation of the upper drum, and can be taken out from the hopper; The lower drum is provided adjacent to the upper drum and is rotatable in the direction opposite to the rotation direction of the upper drum, and is provided on the outer peripheral surface of the lower drum at equal intervals in the circumferential direction. Accordingly, the lower drum has a transfer groove that sequentially matches the take-out groove of the upper drum, receives the rod-shaped article from the take-out groove and transfers it, an outer peripheral guide wall that surrounds the outer periphery of the lower drum, and a side wall that surrounds both sides of the lower drum. Rotate A support port, a discharge port having one end sequentially connected to the transfer groove as the lower drum rotates, and the other end connected to the air feed pipe, and a discharge port connected to the discharge port. A bar-shaped article feeder comprising compressed air injection means for injecting compressed air from the other side wall side of the casing into the transfer groove and discharging the bar-shaped article in the transfer groove to the air feed pipe through the discharge port; Assuming a dual drum type feeder, the feeder of the present invention has the following various features.
[0011]
That is, the feeder according to claim 1 of the present invention relates to one side wall of the hopper located on the rotational entry side of the upper drum, and this one side wall is 1/2 to 3/4 perpendicular to the outer peripheral surface of the upper drum. A lower wall portion extending upward with a first slope angle, and a lower wall portion A vertical wall portion extending upward from the upper end and the upper end of the vertical wall portion An upper wall portion having a second slope angle between the right angle and the first slope angle; Formed in the vertical wall part, Along the lower wall and A blow hole for blowing compressed air toward the outer peripheral surface of the upper drum. Each takeout groove has one suction hole for sucking the rod-like article only at the center in the groove direction. It has become a thing.
[0012]
According to the feeder of claim 1 described above, in the hopper, the rod-shaped article in contact with the lower wall portion of the one side wall has a steep angle of 1/2 or more of the right angle of the first wall of the lower wall portion. The flow velocity is not greatly reduced by the contact with the lower wall portion, and further, by receiving the compressed air flow from the blow hole, toward the outer peripheral surface of the upper drum and along the lower wall portion. Flow immediately. Therefore, as the upper drum rotates, as soon as the upper drum take-out groove enters the outlet of the hopper, the bar-like article that is in contact with the lower wall portion and is located at the lowest position has a fast flow speed toward the take-out groove, By receiving the suction force from the takeout groove, the takeout groove is surely and promptly received.
[0013]
Also, the upper wall portion of one side wall of the hopper has a steeper second slope between the first slope and the right angle of the lower wall portion. However, because there is a vertical wall part between the upper wall part and the lower wall part, Even if rod-like articles are stacked in the hopper up to the height level of the upper wall part, For a bar-shaped article in an area surrounded by an extension line of the upper wall part toward the lower wall part and the lower wall part and the vertical wall part, Weight of bar-shaped article in the upper area near the upper wall Is excessive On the contrary, the flow direction of the rod-shaped article in the upper region deviates greatly from the lower wall part. Fake There is no such thing. Therefore, The compressed air flow from the fumarole is Flow of rod-shaped article along the lower wall Works effectively in this downflow Is not hindered by the weight of the bar-shaped article in the upper region, and a sufficient amount of flow of the bar-shaped article from the upper region toward the lower wall portion is ensured.
[0014]
Also ,Up Even if the rod-shaped article is received in an unstable posture in the take-out groove of the drum, In contrast, Center in the groove direction With only one suction hole Since it is only adsorbed, it contacts the upper bar-shaped article in the hopper in the process of passing through the outlet of the hopper, and as a result, it pivots around its adsorbing position, so that its receiving posture is straight to the takeout groove It is corrected to a normal posture along the shape and is stably held in the take-out groove.
[0015]
Preferably, The casing allows the movement of the lower drum in the axial direction, and supports the drum shaft of the lower drum so as to be rotatable in both the axial direction and the radial direction, and biasing the lower drum in one direction when viewed in the axial direction. Biasing means, and adjusting means for moving the lower drum in the axial direction against the biasing force of the biasing means to adjust the gap between one side wall and the lower drum, and the compressed air injection means A cylindrical member that is allowed to move in the axial direction in the other side wall and is airtight, and rotates integrally with the lower drum; and compressed air from the other side wall into the transfer groove through the cylindrical member. Including a compressed air path that enables jetting (Claim 2) .
[0016]
Claim 2 Since the lower drum is allowed to move in the axial direction, the gap between one side wall of the casing and the lower drum is optimally adjusted by the adjusting means. Is in a state of receiving thrust force from the biasing means, and the bearing means, specifically, the deep groove ball bearing, firmly supports the drum shaft of the lower drum in both the axial direction and the radial direction. .
[0017]
On the other hand, on the other side wall side of the casing, a cylindrical member on the lower drum side is fitted in the other side wall in an airtight manner, and a compressed air path is established through the inside of the cylindrical member. There is no gap between the side wall side and the lower drum that causes compressed air leakage.
Therefore, even if the injection pressure of the compressed air injected into the transfer groove through the compressed air path, that is, the air feeding pressure is increased, the leakage of the compressed air is greatly reduced, so that the vibration of the lower drum is suppressed, The lower drum can be rotated at a high speed.
[0018]
More Preferably, the hopper is disposed between the upper drum and another side wall located on the rotation delivery side of the upper drum, and rotates with respect to the upper drum and a scraping roller that rotates in the same direction as the upper drum. And adjusting means for adjusting the gap between the upper drum and the lifting roller. 3 ).
When the take-out groove that has received the bar-shaped article is withdrawn from the exit of the hopper with the rotation of the upper drum, the scraping roller removes the upper bar-shaped article adjacent to the bar-shaped article in the take-out groove upward. The removal of the bar-shaped article from the outlet of the hopper is facilitated. Further, since the gap between the scraping roller and the upper drum can be adjusted, the gap can be adjusted according to the diameter of the rod-shaped article, and the contact between the rod-shaped article in the take-out groove and the scraping roller can be adjusted. Is avoided, and biting of the bar-shaped article between the scraping roller and the take-out groove is prevented.
[0019]
The groove depth and pitch of the take-out groove are set so as to prevent contact between the upper drum and the other stick-like article in the hopper in which the bar-like article in the take-out groove is laminated on the upper side. Are preferred (claims) 4 ). In this case, even if the rotational speed of the upper drum is increased, the upper drum does not come into contact with a bar-shaped article other than the bar-shaped article received in the take-out groove, and the bar-shaped article is not damaged by the contact.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows an example in which the rod-shaped article feeder of the present invention is applied to a filter cigarette manufacturing system. The filter cigarette manufacturing system includes a plurality of filter attachments 2, a filter rod feeder 4 that is a rod-shaped article, and an air feed pipe 6 that connects between the filter attachment 2 and the corresponding feeder 4. Each feeder 4 feeds a filter rod through an air feed pipe 6 toward the corresponding filter attachment 2, more specifically, its rod hopper.
[0021]
Here, the filter attachment 2 receives not only the filter rod from the feeder 4 but also the cigarette rod manufactured by the cigarette manufacturing machine, and manufactures the filter cigarette from the cigarette rod and the filter rod. .
As shown in FIG. 2, the feeder 4 includes a hopper 8 that stores the filter rod F, and the lower end outlet of the hopper 8 is closed by the upper drum 10. The upper drum 10 is a grooved drum having a plurality of extraction grooves 12 on the outer peripheral surface thereof, and the extraction grooves 12 are arranged at equal intervals in the circumferential direction of the upper drum 10. The upper drum 10 is rotated counterclockwise as shown by an arrow A in FIG. Accordingly, the take-out groove 12 that has entered the lower end outlet of the hopper 8 with the rotation of the upper drum 10 can receive the filter rods F in the hopper 8 one by one.
[0022]
The hopper 8 has one side wall 14 located on the rotational entry side of the upper drum 10 and another side wall 16 located on the rotational delivery side thereof, and the lower end outlet of the hopper 8 as viewed in the rotational direction of the upper drum 10. Is defined between the side walls 14 and 16.
The one side wall 14 has an inner wall surface facing the inside of the hopper 8 formed as a lower wall portion 18, a vertical wall portion 20, and an upper wall portion 22 from the outer peripheral side of the upper drum 10, and the lower wall portion 18 is perpendicular to the horizontal plane. The first gradient θ in the range of 1/2 to 3/4 of ₁ Have Specifically, the first gradient θ ₁ Is set to 60 °, for example.
[0023]
The upper wall portion 22 has a first gradient θ ₁ Larger second gradient θ ₂ And this second gradient θ ₂ Is vertical (right angle) and the first gradient θ ₁ Is set to 76 °, specifically 76 °.
The vertical wall portion 20 is provided as necessary, and the upper wall portion 22 may be directly connected to the lower wall portion 18. Further, the gradient of the other side wall 16 of the hopper 8 is not particularly limited, but the first gradient θ of the lower wall portion 18 is not limited. ₁ It is preferable that it is comparable.
[0024]
Further, a plurality of blow holes 24 are opened in the vertical wall portion 20, and these blow holes 24 have a predetermined interval in the depth direction of the hopper 8, that is, in the axial direction of the filter rod F in the hopper 8. Has been placed. Each blow hole 24 communicates with an air blow passage 26 extending in one side wall 14, and the air blow passage 26 is connected to an air pressure source outside the hopper 8. Bright from Figure 2 Et Thus, the air holes 24 are inclined with the same gradient as that of the lower wall portion 18, whereby the compressed air injected from the air holes 24 flows along the lower wall portion 18.
[0025]
On the other hand, the hopper 8 includes a scraping roller 28 on the other side wall 16 side. The scraping roller 28 is disposed so as to face the hopper 8 from between the other side wall 16 and the outer periphery of the upper drum 10, and is rotated in the same direction as the upper drum 10, that is, counterclockwise as viewed in FIG.
The scraping roller 28 can be brought into contact with and separated from the outer peripheral surface of the upper drum 10, thereby receiving the gap between the scraping roller 28 and the upper drum 10, that is, the scraping roller 28 and the take-out groove 12. The gap E between the filter rod F and the filter rod F is adjusted according to the diameter of the filter rod F. Specifically, when the diameter of the filter rod F is 8 mm, the gap E is preferably set to about 1.8 mm.
[0026]
More specifically, as shown in FIG. 3, the scraping roller 28 is attached to the roller shaft 30 at a predetermined interval. One end of the roller shaft 30 is loosely inserted into a frame 32 of the feeder 4, that is, a hole 34 formed in the frame 32, and is rotatably supported by a mounting disk 38 via a bearing 36. The mounting disk 38 is fastened to the frame 32 via a plurality of mounting bolts 40. Here, the mounting bolt 40 is screwed into the frame 32 through an arc-shaped bolt insertion hole 42 formed in the mounting disk 38.
[0027]
On the other hand, the other end of the roller shaft 30 is connected to one end of a drive shaft 46 via a coupling 44. The drive shaft 46 passes through the sleeve 48 in an eccentric state with respect to the outer peripheral surface of the sleeve 48. Both ends of 48 are rotatably supported via bearings 50. Note that the sleeve 48 itself is rotatably supported by the frame 32.
[0028]
A pulley 52 is attached to the other end of the drive shaft 46, and the pulley 52 and a pulley (not shown) on the electric motor 54 side are connected via an endless belt 56. Therefore, when the electric motor 54 is driven, the driving force is transmitted to each of the scraping rollers 28 via the driving shaft 46 and the roller shaft 30. As a result, the scraping rollers 28 are in the same direction as the upper drum 10. At a predetermined speed, specifically, at a peripheral speed corresponding to the diameter of the filter rod F. That is, the electric motor 54 can arbitrarily set the circumferential speed of the scraping roller 28.
[0029]
Here, when the sleeve 48 is rotated in a state where the fastening of the mounting disk 38 by the mounting bolt 40 is released, the drive shaft 46 is eccentric with respect to the sleeve 48, so that the drive is performed as shown in FIG. The shaft 46 moves in the radial direction within the sleeve 48, and as a result, each scraping roller 28 comes into contact with and separates from the upper drum 10, so that the above-described gap E can be adjusted.
[0030]
On the other hand, as is apparent from FIG. 2, when the upper drum 10 is viewed in a cross section, the take-out groove 12 Around However, when viewed in the axial direction of the upper drum 10, each take-out groove 12 has three groove portions 12a, 12b, 12c as shown in FIG. A divided structure is formed.
[0031]
The upper drum 10 is integrally connected to the drum shaft 58 via a key 59, and the key 59 is positioned at one end of the upper drum 10. The drum shaft 58 extends through the upper drum 10, and both end portions thereof are rotatably supported by the frame 32 via bearings 60. A gear 62 is attached to one end of the drum shaft 58, and a driving force is input to the other end, whereby the upper drum 10 rotates at a predetermined speed.
[0032]
Each extraction groove 12 has an adsorption hole 64 opened only at the bottom of the central groove portion 12 b, and the adsorption hole 64 communicates with an axial hole 66 in the upper drum 10. That is, as shown in FIG. 6, the upper drum 10 is formed with independent axial holes 66 corresponding to the suction holes 64 of the groove portions 12b. These axial holes 66 are opened at the other end face of the upper drum 10, and these open ends are distributed on the same circle at equal intervals.
[0033]
A control ring 68 is in close contact with the other end surface of the upper drum 10, and this control ring 68 surrounds the drum shaft 58 of the upper drum 10 and is fixed to the frame 32 side. That is, when the upper drum 10 is rotated, the other end surfaces are in sliding contact with the control ring 68 in an airtight manner.
An arcuate suction groove 70 as shown in FIG. 7 is formed in the control ring 68 on the end surface in contact with the other end surface of the upper drum 10. The suction groove 70 has a radius of curvature substantially the same as the distribution diameter of the axial hole 66 described above, and extends over a substantially half circumference of the control ring 68. Therefore, when the upper drum 10 is rotated, the open ends of the axial holes 66 are sequentially communicated with the suction grooves 70.
[0034]
On the other hand, the suction groove 70 communicates with an axial hole 72 in the control ring 68, and this axial hole 72 is connected to an external suction hose 76 through an internal passage (not shown) in a connection ring 74 adjacent to the control ring 68. The suction hose 76 is connected to a negative pressure source. The connection ring 74 is also a fixing member, like the control ring 68.
[0035]
Therefore, when the suction groove 70 of the control ring 68 is constantly supplied with a predetermined suction pressure from the negative pressure source, and when the axial hole 66 of the upper drum 10 communicates with the suction groove 70, that is, When the axial hole 66 passes through the suction area S defined by the suction groove 70, the suction force is supplied to the corresponding suction hole 64, that is, the take-out groove 12 through the axial hole 66.
[0036]
Here, as shown in FIG. 2, when viewed in the rotational direction of the upper drum 10, the suction area S is a region beyond the position immediately before the one side wall 14 of the hopper 8 beyond the lower end outlet of the hopper 8, that is, It extends over a substantially half circumference.
A lower drum 78 is arranged on the lower side of the upper drum 10 so as to make rolling contact with the upper drum 10, and this lower drum 78 is in a direction opposite to the upper drum 10, that is, clockwise as indicated by an arrow B in FIG. The transfer groove 80 is provided in the outer peripheral surface at equal intervals in the circumferential direction. Specifically, the upper drum 10 and the lower drum 78 are rotated while the takeout groove 12 and the transfer groove 80 are aligned with each other.
[0037]
The lower drum 78 is covered by a casing 82 on three sides. The casing 82 covers an outer peripheral guide 84 that covers the outer peripheral surface of the lower drum 78 and both side surfaces of the lower drum 78 as shown in FIG. The drum 78 includes a pair of left and right side walls 88 and 90 that rotatably support the drum shaft 86 of the drum 78.
More specifically, the outer peripheral guide 84 covers the lower half peripheral portion of the lower drum 78, and a predetermined gap is secured between the inner peripheral surface of the outer peripheral guide 84 and the outer periphery of the lower drum 78. The lower drum 78 rotates without sliding against the outer peripheral guide 84. Specifically, as is apparent from FIG. 8, the outer peripheral guide 84 has a half-divided cylindrical shape having end walls at both ends, and can be supported on the frame 32 side at both ends.
[0038]
In other words, the side wall 88 positioned on one end side of the lower drum 78 is connected to one end portion of the outer peripheral guide 84 and rotatably supports the one end portion of the drum shaft 86 via the deep groove ball bearing 92. Here, the deep groove ball bearing 92 cannot be moved in the axial direction with respect to the drum shaft 86, however, it is attached to the side wall 88 in a state allowing sliding in the axial direction. ing.
[0039]
One end of the drum shaft 86 protrudes from the side wall 88, and a sleeve shaft 96 is attached to the one end via a key 94, and a gear 98 is attached to the sleeve shaft 96. The gear 98 meshes with the gear 62 on the upper drum 10 side, whereby the lower drum 78 is rotated by receiving a driving force from the upper drum 10.
A corrugated washer 100 is mounted in the side wall 88 via a mounting plate 99. The corrugated washer 100 has a shape as shown in FIG. 9 and is disposed coaxially with the deep groove ball bearing 92 so that the deep groove ball bearing 92 is pressed toward the lower drum 78 via the pressing sleeve 102. It is fast. Therefore, the lower drum 78 receives a thrust force toward the other side wall 90 by the corrugated washer 100.
[0040]
Further, an annular hole 103 opened toward the lower drum 78 side is formed in the side wall 88, and an air flange 104 as a cylindrical member is rotatable in the annular hole 103 and slides in the axial direction thereof. Fits freely.
More specifically, the air flange 104 has a cup shape in which one end is opened and the other end is closed, and the outer peripheral surface thereof can be slidably contacted with the inner peripheral surface of the annular hole 103.
[0041]
The other end of the air flange 104 is attached in close contact with one end surface of the lower drum 78 and rotates integrally with the lower drum 78. As is apparent from FIG. 10, communication holes 106 are formed in the outer peripheral portion of the air flange 104 at equal intervals in the circumferential direction. These communication holes 106 open at the other end surface of the air flange 104 and correspond to each other. It is in the state always connected to the transfer groove | channel 80 to do.
[0042]
An input port 108 is opened on the outer peripheral surface of the air flange 104 corresponding to the communication hole 106, and these input ports 108 are arranged at equal intervals in the circumferential direction of the air flange 104.
On the other hand, a supply port 110 is formed in the side wall 88. When the transfer groove 80 reaches a predetermined rotation angle position, that is, a discharge rotation angle position as the lower drum 78 rotates, The transfer groove 80 can be connected via the input port 108 and the communication hole 106 described above.
[0043]
As shown in FIG. 2, the supply port 110 is positioned in the region of the outer peripheral guide 84 and is connected to the compressed air supply pipe 114 via a joint 112 fixed to the outside of the side wall 88. Reference numeral 114 is connected to a pressurized air source via an electromagnetic valve 116.
On the other hand, as shown in FIG. And bearing block 120 The cylinder head 118 has a circular arc shape opened upward as shown in FIG. The cylinder head 118 is supported by the frame 32 described above. And Bearing block 120 To the cylinder head 118 Wearing Has been .
[0044]
In the bearing block 120, the needle bearing 124 and the deep groove ball bearing 126 are sequentially accommodated from the lower drum 78 side. More specifically, the needle bearing 124 rotatably supports the drum shaft 86 in a state where the movement of the drum shaft 86 in the axial direction is allowed. On the other hand, the deep groove ball bearing 126 is paired with the deep groove ball bearing 92 described above, and is supported so as not to move in the axial direction with respect to the drum shaft 86, but in the axial direction with respect to the bearing block 120. Sliding is allowed.
[0045]
Further, an adjustment screw 128 is screwed into the other end portion of the bearing block 120 so as to be coaxial with the drum shaft 86, and one end of the adjustment screw 128 protrudes into the bearing block 120. In the bearing block 120, a pressing disk 130 is slidably fitted between the adjusting screw 128 and the deep groove ball bearing 126, and the pressing disk 130 receives the screw of the adjusting screw 128, so that the deep groove ball The drum shaft 86, that is, the lower drum 78 can be pushed back against the thrust force of the wave washer 100 described above via the bearing 126.
[0046]
Specifically, when the feeder 4 is assembled, the lower drum 78 receives the thrust force generated by the corrugated washer 100, and the other end surface is the side wall 90, that is, its cylinder head 118 and bearing block. One of 120 End face Is in close contact with the Such a close contact state is not preferable in increasing the rotational resistance of the lower drum 78 and increasing the rotational speed thereof.
[0047]
However, in this state, if the adjustment screw 128 is screwed and the lower drum 78 is pushed back through the pressing disk 130 and the deep groove ball bearing 126, the other end surface of the lower drum 78 and the cylinder head 118 and the bearing block 120 are not connected. That is, a desired gap G can be accurately and easily secured between the lower drum 78 and one end surface of the side wall 90, and the size of the gap G increases the rotational resistance of the lower drum 78. Rather, it is set to such an extent that a sufficient pneumatic seal is obtained between the lower drum 78 and the side wall 90.
[0048]
On the other hand, as shown in FIG. 11, the cylinder head 118 has an arc-shaped discharge port 132 formed in the lower portion thereof, and the discharge port 132 has the above-described discharge rotation angle position of the transfer groove 80 of the lower drum 78. When passing, it extends over a predetermined length in the circumferential direction of the lower drum 78 so as to communicate with the transfer groove 80.
Further, a connector nozzle 134 is connected to the other end surface of the cylinder bed 118. This connector nozzle 134 has no arc shape similar to the cylinder head 118 as shown in FIG. A slot 136 is provided. A nozzle portion 138 is connected to the arc slot 136, and the nozzle portion 138 has a flat funnel shape in which one end matches the arc slot 136 and the other end is connected to the air feed pipe 6.
[0049]
Referring again to FIG. 2, the crossover guide 140 is disposed outside the lower drum 78, and this crossover guide 140 is viewed from the upper end located on the upstream side of the outer peripheral guide 84 when viewed in the rotational direction of the lower drum 78. It extends toward the upper drum 10. The base portion of the crossover guide 140 covers the outer peripheral surface of the lower drum 78 so as to form an extension portion of the outer peripheral guide 84, and the tip portion thereof has a comb-teeth shape. It arrange | positions so that each groove part may be pinched | interposed. More specifically, the crossover guide 140 has a shape as shown in FIG. 13, and the comb teeth are symmetrical about the center groove portion 12 b of the takeout groove 12, that is, the suction position X of the filter rod F. . The crossover guide 140 is fixed to the outer peripheral guide 84.
[0050]
Furthermore, a crossover guide 142 is also arranged outside the upper drum 10, and this crossover guide 142 is viewed from the downstream end of the suction area S toward the lower drum 78 as viewed in the rotational direction of the upper drum 10. It extends along the outer periphery of the drum 10.
Next, operation | movement of the feeder 4 mentioned above and its effect | action are demonstrated.
[0051]
14 to 16 sequentially show the state from the state where one empty takeout groove 12 starts to enter the lower end outlet of the hopper 8 to the complete entry into the lower end outlet as the upper drum 10 rotates. As shown in FIG. 16, when the empty takeout groove 12 completely enters the lower end outlet of the hopper 8, the filter rod F in the hopper 8 is immediately received in the takeout groove 12, and the filter rod F is adsorbed in the adsorption hole 64 of the take-out groove 12. Thereafter, the filter rod F is pulled out from the lower end outlet of the hopper 8 together with the take-out groove 12 and is transferred toward the lower drum 78.
[0052]
Here, the compressed air injected along the lower wall portion 18 from one side wall 14 of the hopper 8, that is, the vertical hole portion 20 of the vertical wall portion 20, moves the filter rod row in contact with the lower wall portion 18 to the upper drum 10. On the other hand, the take-out groove 12 entering the lower end outlet of the hopper 8 receives supply of suction pressure to the suction hole 64 immediately before entering the lower end of the filter rod row. Aspirate the filter rod F at Therefore, the lowest filter rod F has a fast flow speed toward the take-out groove 12. Flow down Then, it is quickly received by the take-out groove 12 and is reliably adsorbed by the adsorbing hole 64.
[0053]
The lower wall portion 18 has a first gradient θ ₁ Is set to a range of ½ to ¾ of a right angle as described above, that is, 60 °, the weight of the filter rod row does not work excessively on the lowest filter rod F, Conversely, the lower wall portion 18 is not substantially supported. As a result, the filter rod row receives the jet of compressed air from the blow holes 24, and smoothly and rapidly flows toward the outer peripheral surface of the upper drum 10, that is, the take-out groove 12 that sequentially enters the lower end outlet of the hopper 8. Can flow down.
[0054]
Furthermore, even if the filter rod F is full in the hopper 8, the second gradient θ of the upper wall portion 22 is obtained. ₂ Is right angle and the first gradient θ ₁ The weight of the upper region filter rod F in the stacked state at the height level of the upper wall portion 22 does not work excessively on the filter row. On the contrary, the flow of the filter rod F in the upper region does not go in a direction deviating from the lower wall portion 18. Therefore, the filter rod F in the upper region is smoothly guided toward the lower wall portion 18 in the process in which the filter rods F of the filter rod row are sequentially received in the take-out groove 12, and the above-mentioned along the lower wall portion 18. The filter rod row can be generated stably.
[0055]
As a result, even when the rotational speed of the upper drum 10 is increased, the take-out groove 12 can reliably receive the filter rod F as soon as it enters the lower end outlet of the hopper 8, and the take-out that has entered the lower end outlet of the hopper 8. All the grooves 12 are pulled out from the lower end outlet of the hopper 8 in a state where the filter rod F is received, whereby the filter rod F can be stably taken out from the hopper 8.
[0056]
On the other hand, since only one suction hole 64 of each takeout groove 12 is provided at the center, the filter rod F adsorbed in an unstable manner in the takeout groove 12 rotates around the suction position. It is in an acceptable state. Therefore, the unstable receiving posture of the filter rod F with the unstable receiving posture in the take-out groove 12 is corrected by the contact with another filter rod F in the process before coming out from the lower end outlet of the hopper 8. , And is securely received and held in the take-out groove 12.
[0057]
Further, the scraping roller 28 of the hopper 8 removes the filter rod F adjacent to the filter rod F upward when the filter rod F is taken out from the lower end outlet of the hopper 8 together with the take-out groove 12. F can be taken out smoothly. At this time, since a predetermined gap E is secured between the scraping roller 28 and the filter rod F in the take-out groove 12, the cross section of the filter rod F is a perfect circle. Even without this, the filter rod F does not get caught between the scraping roller 28 and the take-out groove 12, and contributes to stable removal of the filter rod F.
[0058]
Further, as shown in FIG. 17, when the takeout groove 12 moves in the lower end outlet of the hopper 8, the other filter rods F other than the filter rod F received in the takeout groove 12 are in the takeout groove 12. The receiving filter rod F prevents contact with the outer periphery of the upper drum 10.
That is, with respect to the take-out groove 12, the groove depth and pitch interval are appropriately set, and contact between the other filter rod F and the outer periphery of the upper drum 10 is prevented. For example, in order to reduce the diameter of the upper drum 10, when the pitch interval of the extraction grooves 12, that is, the groove interval of the extraction grooves 12 is set to about the radius of the filter rod F, the groove of the extraction groove 12 is used. By setting the depth to about 55 to 60% of the diameter of the filter rod F, the contact between the other filter rod F and the upper drum 10 can be reliably prevented.
[0059]
In FIG. 17, when the groove depth of the extraction groove 12 is deep as shown by a two-dot chain line, the other filter rod F may come into contact with the outer periphery of the upper drum 10, and in this case, the rotation of the upper drum 10 If the speed is high, other filter rods F may be damaged by the upper drum 10. However, in the present embodiment, such a problem can be solved.
[0060]
As described above, the filter rod F taken out from the hopper 8 is transferred toward the lower drum 78 as the rotation of the upper drum 10 proceeds. At this time, the filter rod F is removed from the suction area S described above. At this time, the suction of the filter rod F is released. However, at this time, since the crossing guide 142 is disposed outside the upper drum 10, the filter rod F is transferred toward the lower drum 78 without dropping from the take-out groove 12.
[0061]
Then, when the filter rod F reaches the lower drum 78, and when the take-out groove 12 and the transfer groove 80 of the lower drum 78 are matched, the adsorption of the filter rod F has already been released. While being guided by the guide 140, it is transferred from the take-out groove 12 to the transfer groove 80, and thereafter, the transfer is continued with the rotation of the lower drum 78.
[0062]
Here, as described above, since the tip of the crossover guide 140 has a comb-teeth shape symmetrical about the suction position of the filter rod F, the crossover guide 140 is connected to the filter from the takeout groove 12 to the transfer groove 90. The delivery of the rod F can be performed stably.
Thereafter, when the transfer groove 80 that has received the filter rod F reaches the aforementioned discharge rotation angle position, the supply port 110 of the side wall 88 and the inlet port 108 of the air flange 104 that forms a pair with the transfer groove 80 communicate with each other. The high-pressure compressed air supplied from the pressurized air source into the compressed air supply pipe 114 through the previously opened solenoid valve 116 is jetted into the transfer groove 80 through the communication hole 106 of the air flange 104. The compressed air discharges the filter rod F in the transfer groove 80 to the air feed pipe 6 through the discharge port 132 of the cylinder head 118 and the connector nozzle 134, and the discharged filter rod F corresponds to the air through the air feed pipe 6. It is sent to the filter attachment 2 by air.
[0063]
Here, as described above, the lower drum 78 receives the urging force of the corrugated washer 102 and is in a state of receiving a thrust force in the axial direction thereof, so that the deep groove ball that rotatably supports the drum shaft 86 of the lower drum 78. The bearings 92 and 126 firmly support the drum shaft 86 in both the axial direction and the radial direction.
Further, the lower drum 78 is allowed to move in the axial direction, and the axial position of the lower drum 78 can be adjusted by the screwing amount of the adjusting screw 128 described above. Therefore, the gap G between the lower drum 78 and the side wall 90 is set. Even if high-pressure compressed air is jetted into the transfer groove 80, the high-pressure compressed air does not leak through the gap G, and the side wall 90 is not connected to the lower drum. Since the rotational resistance of the rotational resistance of 78 is not greatly increased, the lower drum 78 can be rotated at a high speed.
[0064]
On the other hand, the side wall 88 and the lower Mu With respect to the rotational support structure between the lower drum 78 and the lower drum 78, the lower drum 78 is rotatably slidably supported on the side wall 88 via the cylindrical air flange 104, so that the rotational resistance of the lower drum 78 is not increased. The lower drum 78 can be rotated at a high speed, and the airtightness between the side wall 88 and the air flange 104 can be easily secured.
[0065]
The gap between the lower drum 78 and the outer periphery guide 84 is easily set to a desired value by adjusting the axis of the lower drum 78 and the outer periphery guide 84.
As a result, both the rotational speeds of the upper drum 10 and the lower drum 78 can be increased, so that the supply speed of the filter rod F from the feeder 4 can be significantly increased.
[0066]
Further, even if high-pressure compressed air is intermittently injected into each transfer groove 80 of the lower drum 78, the leakage of high-pressure compressed air from the lower drum 78 is small, and the consumption efficiency of compressed air is improved. The drum shaft 86 of the lower drum 78 is firmly supported by the deep groove ball bearings 92 and 126 in a state of receiving a thrust force, so that intermittent discharge of compressed air causes the lower drum 78 to vibrate in the front, rear, left and right directions. Nor.
[0067]
The ejection of the high-pressure compressed air reduces the time required for discharging the filter rod F from the lower drum 78 to the cylinder head 118, so that the filter rod F is also clogged between the lower drum 78 and the cylinder head 118. In addition to being prevented, the air feed distance of the filter rod F from the feeder 4 is greatly extended.
[0068]
Although the present invention has been described by being applied to the feeder 4 that supplies the filter rod F toward the filter attachment 2, the present invention can be similarly applied to a feeder for other rod-shaped articles other than the filter rod. .
The illustrated embodiment shows an example for carrying out the present invention, and the supply machine of the present invention can be variously modified without departing from the gist thereof.
[0069]
【The invention's effect】
As described above, according to the bar-shaped article feeder of the present invention (Claim 1), the compressed air is jetted along the lower wall portion of one side wall of the hopper located on the rotational entry side of the upper drum. While providing fumaroles, the slopes of the lower and upper side wall portions are Respectively Setting And a vertical wall portion is interposed between the lower wall portion and the upper wall portion. Thus, the bar-shaped article can be stably taken out from the hopper by the upper drum, and the upper drum can be rotated at high speed.
[0070]
And Since the take-out groove of the upper drum only adsorbs the bar-shaped article only in the center in the groove direction, the bar-shaped article is allowed to turn around the adsorbing position, and the upper drum rotates due to the high-speed rotation of the upper drum. Even if the receiving posture is uneasy, the receiving posture can be corrected to a stable posture, and the upper drum can be rotated at a high speed.
[0071]
According to the feeder of the invention (claims) 2 ), The gap between the lower drum and one side wall is adjusted in a state where the lower drum receives a thrust force in the axial direction thereof, and the other side wall side passes through the inside of the cylindrical member. Since the compressed air path to the transfer groove is formed, high-pressure compressed air can be ejected into the transfer groove while allowing the lower drum to rotate at a high speed.
[0072]
When the gap between the hopper scraping roller and the upper drum is adjustable (claims) 3 ), The clogging of the bar-shaped article is prevented between the scraping roller and the take-out groove of the upper drum, and the bar-shaped article can be stably taken out from the hopper.
With regard to the take-out groove of the upper drum, its depth and pitch interval are set appropriately (claims 4 ), The rod-shaped article received in the take-out groove prevents contact between the other rod-shaped article at the outlet of the hopper and the outer periphery of the upper drum, and damage to the rod-shaped article due to this contact is prevented.
[Brief description of the drawings]
FIG. 1 is a schematic block diagram showing a filter cigarette manufacturing system.
FIG. 2 is a schematic cross-sectional view of the filter rod feeder in FIG.
FIG. 3 is a view showing a support structure of the scraping roller in FIG. 2;
4 is an arrow view from the direction IV in FIG. 3;
FIG. 5 is a longitudinal sectional view of the filter rod feeder of FIG.
6 is a cross-sectional view of the upper drum of FIG.
7 is a cross-sectional view of the control ring of FIG.
8 is a longitudinal sectional view of the outer periphery guide of FIG.
9 is a side view of the corrugated washer of FIG. 5. FIG.
10 is an end view of the air flange of FIG.
11 is an end view of the cylinder head of FIG. 5. FIG.
12 is an end view of the connector nozzle of FIG. 5. FIG.
13 is a plan view of a crossing guide between the drums of FIG. 5. FIG.
FIG. 14 is a view showing a state in which an empty takeout groove starts to enter the lower end outlet of the hopper in the upper drum.
15 is a diagram showing a state in which the rotation of the upper drum has advanced from the state of FIG.
16 is a view showing a state where an empty takeout groove has completely entered the lower end outlet of the hopper from the state of FIG. 15 and has received the filter rod.
FIG. 17 is an enlarged view of a part of the lower end outlet of the hopper.
[Explanation of symbols]
2 Filter attachment
4 Filter rod feeder
6 Air pipe
8 Hoppers
10 Upper drum
12 Unloading groove
14 One side wall
18 Lower wall part
20 Vertical wall part
22 Upper wall part
24 Fumarole
28 Raising roller
38 Mounting disc (adjustment means)
48 Sleeve (Adjustment means)
64 Adsorption hole
78 Lower drum
80 Transfer groove
82 casing
86 Drum shaft
88 Side wall (other side)
90 Side wall (one side)
92 Deep groove ball bearing (bearing means)
100 Wave washer (biasing means)
104 Air flange (cylindrical member)
106 communication hole (pressure air route)
108 Input port (compressed air route)
110 Supply port (pressure air path)
118 Cylinder head
126 Deep groove ball bearing
128 Adjustment screw (Adjustment means)
132 Discharge port
134 Connector nozzle

Claims (4)

A hopper for storing rod-shaped articles;
An upper drum provided to be rotatable in one direction with the outlet of the hopper closed at the outer peripheral surface;
It is provided on the outer peripheral surface of the upper drum at equal intervals in the circumferential direction, and sucks and receives the bar-shaped articles in the hopper one by one when passing through the outlet of the hopper as the upper drum rotates. A take-out groove that can be taken out from the hopper;
A lower drum provided adjacent to the upper drum and rotatable in a direction opposite to the rotational direction of the upper drum;
It is provided on the outer peripheral surface of the lower drum at equal intervals in the circumferential direction, and sequentially matches the take-out groove of the upper drum as the lower drum rotates, and receives and transfers the rod-shaped article from the take-out groove. A transfer groove;
A casing that has an outer peripheral guide wall that surrounds the outer periphery of the lower drum and a side wall that surrounds both side surfaces of the lower drum, and supports the lower drum rotatably;
A discharge port provided on one side wall of the casing, one end sequentially communicating with the transfer groove along with the rotation of the lower drum, and the other end connected to an idle pipe;
Compressed air injection means for injecting compressed air from the other side wall side of the casing into the transfer groove communicated with the discharge port, and discharging a rod-shaped article in the transfer groove to the air feed pipe through the discharge port; In the provided bar-shaped article feeder,
One side wall of the hopper located on the rotational entry side of the upper drum is
A lower wall portion extending upward from the outer peripheral surface of the upper drum with a first gradient angle of 1/2 to 3/4 perpendicular to the upper drum;
A vertical wall portion extending upward from an upper end of the lower wall portion;
An upper wall portion connected to an upper end of the vertical wall portion and having a second slope angle between a right angle and the first slope angle;
Wherein formed on the vertical wall portion, seen including a fumarole for ejecting compressed air toward the outer circumferential surface of and the upper drum along said lower wall portion,
Each take-out groove has a single suction hole for sucking the rod-shaped article only in the center in the groove direction . Before Symbol casing,
Bearing means for allowing movement of the lower drum in the axial direction and rotatably supporting the drum shaft of the lower drum in both the axial direction and the radial direction;
A biasing means for biasing the lower drum in one direction when viewed in the axial direction;
Adjusting the gap between the one side wall and the lower drum by moving the lower drum in the axial direction against the biasing force of the biasing means;
The compressed air injection means includes
A cylindrical member that is fitted in the other side wall in a state in which axial movement is allowed and airtight, and rotates integrally with the lower drum;
2. The bar-shaped article feeder according to claim 1, further comprising: a compressed air path through which compressed air can be ejected from the other side wall into the transfer groove through the cylindrical member. The hopper
A scraping roller disposed between the other side wall located on the rotation delivery side of the upper drum and the upper drum, and rotating in the same direction as the rotation direction of the upper drum;
3. The adjusting device according to claim 1 , further comprising an adjusting unit that adjusts a gap between the upper drum and the lifting roller by moving the scraping roller toward and away from the upper drum. Bar-shaped article feeder. The groove depth and pitch of the take-out groove are set so as to prevent contact between the upper drum and the other stick-like article in the take-up groove in a stacked state on the upper side. The bar-shaped article feeder according to any one of claims 1 to 3 .

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