NO137846B - FEEDING NOZZLE FITTED FOR USE IN COLLABORATION WITH A STEP FORM - Google Patents

Description

Device for fishing reels with a line guide pin that can be pulled into a rotatable line guide cover.

The invention also relates to fishing reels

over a stationary line spool downwards, for winding the line on the spool rotatable line guide sleeve, with a line guide pin stored in the sleeve which can be pushed out through and drawn into the sleeve, and which is influenced by a spring towards its retracted position and is automatically pushed by a cam out to the active position by rotation of the cap, which pin is released for retraction by the action of a ■maneuvering device which can be influenced from outside the reel, so that the line can be freely pulled off the reel.

Various constructions of such

devices have previously been proposed, in which the lace guiding pin or a slide carrying it, is radially displaceably guided in the lace guiding sheath, and in which the maneuvering member is arranged to provide a relative displacement between the lace guiding sheath and a centrally arranged cam in this, such as when acting on the maneuvering member is displaced out of the two-way path of the pin or pin slide and leaves it free for internal calculation during

impact of its feather. When the operating member is released, the cam and the string guide cap are returned by a return spring towards their initial position, but

is prevented from completing this relative movement of the pin slide, resp. the pin which is in its inner retraction position. The cam and the slide then collide with each other with their faces turned in the axial direction, and the pin remains retracted. First

by rotation of the cover with the pin slide, the cam becomes active and the slide is displaced outwards by this with the pin in the extended position. Only then are the cam and the string guide cap free to complete their relative movement under the action of the return spring. Underneath, the inner end of the stiffening slide interacts with a concentric surface on the cam member, against which it always abuts during rotation of the lubrication guide cap.

Such devices are made in different ways. In one case, the cam is axially displaceable by means of the maneuvering member, while the cord guide sheath is not axially displaceable (see U.S. Patents 2,668,025 and 2,675,192). In the case of these devices, it is thus the cam that is displaceable in and out of the path of movement for the pin slide, which is designed as an inward extension of the shoe guide stiffener. In the second case, the lace guide cap is axially displaceable together with the pin slide, while the camorigan net is fixed in relation to the stand of the reel (see e.g. US patent 2 828 088). The latter device has been used for fishing reels of the kind where the line guide cover is provided with a brake ring, which, during the axial displacement of the cover, cooperates with an outer cap that encloses the entire spool device for braking the line against it.

The invention is based on a device where the pin slide is removed from the cam member after its extension movement initiated by the cam member, so that there is no unnecessary wear and no frictional resistance during winding.

The invention comprises a device for reel reels, with a line spool fixed in a stand, a 1-stand rotatable but not axially displaceable line guide cover, a line guide pin that can be extended out of the cover and retracted into the cover, a pin sieve that carries the pin and is controlled radially in the interior of the shoelace casing and which is actuated radially inwards by a spring, a release device which can be actuated from the outside of the reel, so that. it is displaced axially against the action of a return spring from a rest position in which the release train normally holds the pin slide in the extension position, and to a release position in which the pin slide can freely move radially inward with the help of the spring, as well as a fixed in the stand comb for pushing back the pin slide when the line guide cap rotates to wind up the line on the spool.

The invention is characterized by the fact that the pin slide can also be swung around the hole in the string guide cap in the axial plane of the spool and that the release device is provided with a part that interacts with the pin slide which, when the release device returns to its rest position under the influence of a spring, swings the inner end of the pin slide within the operating area of the push-out cam.

Three embodiments of the invention are shown schematically in the attached drawings.

Fig. 1 is a half axial section through a fishing reel according to a first embodiment of the invention. Fig. 2 is a section mainly along the line II—II in fig. 1. Fig. 3 shows part of a section similar to that shown in fig. 1 with the parts 1 a different functional position. Fig. 4 is a partial section through a fishing reel according to another embodiment of the invention. Fig. 5 shows slime embodiment 1 in another functional position. Fig. 6 is a partial section through a third embodiment of the invention. Fig. 7 shows the same design in another functional position. In fig. 1 shows the following known parts: A stand 1, which in its lower part contains a drive device comprising a shaft 2 which can be turned by means of a crank not shown, a pinion wheel 3' placed on a hub, a toothed gear 4 which engages this, and a shaft '5' firmly connected to this gear 4, which extends upwards through a belly 6, which forms a centering pin for a non-rotatable lace spool 7. On the upper end of the shaft 5 above the hub 6 and the spool 7, a lace guide cap 8 is attached , whose edges extend downwards beyond the upper flange of the spool 7. On the stand 1 is fixed a 1 cap 9, which encloses the spool and the lubrication guide cap 8, with an upper central outlet hole 10 for the line 11, which from coil 7 ! runs around the lower edge of the lace guide cap, along its outer side to the hole 10.

According to the invention, the shaft 5 is hollow, and 1 it is axially displaceable controlled by a spindle part 12. The spindle 12 is influenced in the downward direction by a spring 13, which is clamped between an upper ledge on the shaft 5 and. a lower ledge on the spindle 12. The lower end of the spindle 12 rests against a maneuvering device, with the help of which the spindle can be moved upwards in a known manner under compression of the spring 13. On the upper end of the spindle 12 above the lace guide cap 8 is attached a disk 14, on which is placed an annular brake shoe 15 of rubber or similar material.

The cord guide cap 8 is provided on its outer, mainly axially extending peripheral part with a hole for a cord guide pin 16. This pin 16 consists of a replaceable sleeve of hard metal, or similar, which is threaded onto a stud 17 on a pin slide 18, which extends radially. inwards from the staple.. This staple sieve is provided with. a radial slot 19, in which' a. guide pin 20, which sticks down on the inside of the upper part of the lace guide cap 8, enters. The pin slide 18 is further provided with an upward projection 21, which exhibits a radially inwardly facing, obliquely upward and outwardly sloping abutment surface 22. The projection 21 partially protrudes into an opening 23 in the cord guide sheath 8, and lies with its inclined surface 22 on towards the edge 14A of the disk 14, when the pin 16 is in the extended position, as shown in fig. 1. Against a fleins. 25 on the inner end of the pin sleeve 16 rests on a leaf spring 26, which has a hole for the pin

16„ and whose ends rest against the inner side

of the mantle. This spring 26 seeks to push the pin and the pin slide 18 radially inwards and at the same time to hold the pin slide 18 in the one in fig. 1 showed horizontal position. An annular or polygonal leaf steel spring 24, which is bent like that in fig. 1 shown profile, is fixed at 27 on the inner side of the lace guide cover on both sides of the cover's attachment point on the shaft 12, fig. 2.

The device described above works in the following way: When in the one in fig. 1 shown position of the parts turns the shaft 2 with the help of its not shown crank, the cord guiding sheath is set in rotation at the parts 3, 4 and 5, under which the pin 16 protruding from the sheath receives the cord and winds it. up on the coil 7. When one knows hjielp. by the not shown maneuvering device, the spindle 12 is pushed upwards, the disc 14 with the brake shoe 15 is shifted upwards, under which the brake shoe, 15 in the clamping cord 11 towards the inside of the cap 9. At the same time, the edge 14A of the disc 14 is moved upwards; so that the stop flap 22 on the protrusion 21 becomes free and the pin slide 18 is displaced, radially inwards, until the outer end of the slot 1.9' rests against the guide pin 20'. When, at the end of the casting movement, the fisherman releases the maneuver-reimgsorgan, the brake shoe 15, the disk 14 and the spindle 12 are displaced again downwards by the spring 13. Then it is achieved in fig. 3 shown position. The disc 14 now hits the upper side of the protrusion 21, since the pin slide 18' is in its inner end position. By the force of the spring 13, the pin slide 18' is pressed downwards, so that it rotates around the end of the pin 16, which still engages in the hole in the lace guide cap 8, and so that its inner end is pressed downwards on the upper end surface' 28 of the hub 6. This end surface is provided with a comb-shaped part 29 which forms an axial projection on the end of the hub. Should the inner end of the pin slide hit the upper side of the cam projection 29, this has no significance. The only consequence is that the disk 14 is stopped somewhat higher than shown in fig. 3. The blade-shaped spring 24 affects the pin slide upwards, but is weaker than would be necessary to overcome the action of the spring 13.

When the fisherman, after completing the cast, begins to crank in the line, the line guide cap begins to rotate and closes the hole for the pin and the guide pin 20 to bring it into the position in fig. 3 remaining - Stiftsieide 18. in this rotation. The inner end of the pin slide then slides on the end surface 28 of the hub (or if it rests against the upper side of the hub, first on this and then down on the surface 28) until it hits the edge of the cam member 29, by which the pin slide 18 is guided outwards. As soon as the upper end of the abutment surface 22 on the protrusion 21 during this movement reaches the edge 14A of the disk 14, this can move downwards into the position shown in Fig. 1, at the same time that the pin slide 18 of the springs 24 and 26 is swung again up. Due to the inclination of the stop surface 22, the pin slide 18', in addition to its outward movement affected by the cam member 29, receives an additional movement pulse, radially outwards, whereby the inner end of the pin slide 18 will surely be removed from the cam 29. The parts have then fully occupied again, the position shown in Fig. 1.

With the device described above, one can arrange two diametrically opposite cord guide pins with pin sieves and associated organs in a precisely symmetrical arrangement in relation to the cord guide cap's 8 axis of rotation. However, the construction does not need to. to be changed, except with regard to the attachment of the bias spring 24, if. it is only arranged, a pin.

The embodiment shown on fig. 4 and 5 differs from that shown on fig. 1

—3' by a different design of the pin slide or pin slides and of the blocking means which depend on displacement of the brake shoe. The pin slide here has the form of a plate 30' sloping slightly downwards in relation to the pin shaft with two vertically downward-facing flanges 31 which terminate its two sides parallel to the pin shaft. In the plate there is a longitudinal slot 32. The locking disc 33, which corresponds to the locking bolt 14 in fig. I and 3, which in this case is made up of a separate part, which is however firmly connected to the brake shoe' 34, is in this case provided for each pin side with a pin 35 protruding through a hole 1 in the upper part of the lace guide cap 8', which extends down through the slot 32 in the pin slide 30. A sleeve 36 is attached to the lower end of the pin 35, with a flange 37 at the lower end. The sleeve 36 serves as a guide for the slot during the radial displacement of the pin slide 30 and its flange 37 limits the pin slide's rotation downwards around the penetration of the pin 16 in the lace guide cap 8. A disc 38 is threaded onto the pin 35, which is normally held in contact with the upper end of the sleeve' 36' of an annular leaf spring 39 of a similar nature to the spring 24 in fig. 1, however with the difference that the spring exerts a downward force on the disk. The central hole in the disc 38 which is threaded on the pin 35 and the conical transition fiats between the pin's narrower middle part and its end parts ensure a complete centering of the disc 38 in its in fig. 4 showed normal position

without preventing an oblique Unling of the disc in other positions. The disc's outer circumference is designed as a downwardly tapered conical surface, and on the upper side of the slide 30, a stop surface 40 is designed, which in the normal position is inclined downwards inwards, corresponding to the disc's conicity. The other parts are mainly designed in the same way as with the one in fig. 1 shown embodiment, and is provided as needed

.with a corresponding reference number. Two or

four, possibly more pin slides with associated pins 16, pins 35, washers 28 and arms of the spring 39 can be symmetrically arranged around the axis of the reel.

When the spindle 12 is displaced upwards, the disk 33 and the brake shoe 34 are raised together with the pins 35 in relation to the snow removal cap 8. The flange 37 of the sleeve 36 lifts the inner end of the pin slide. The disc 38 is held in a horizontal position by the spring 39, while the pin slide's plate 30 reduces its inclination in relation to the horizontal plane. Thereby, the stop surface 40 is displaced down from the edge of the disk 38 and frees the pin slide for displacement radially inwards during retraction of the pin 16. When the inner end of the plate 30 is lifted above the level of the upper side of the cam 29, there is nothing to prevent displacement of the slide inwards under the influence of the lamellar spring 26. When the spindle 12 is again released for displacement downwards under the influence of its return spring, which in this case can be constituted by the spring 39, the inner end of the pin slide 30 is turned down towards the upper side of the cam 29, or towards the upper end surface 28 of the hub 6, as shown in fig. 5. From this figure it is clear that the forefoot shoe 34 here below is brought all the way back to its starting position, and not, as is clear from fig.

3 for the disc 14, is left at some distance from its lower contact position towards the upper side of the cover 8. In the device according to fig. 4 and 5, the stiff slide 30 remains in contact with the hub or the cam, while the flange 37 of the sleeve 36 continues to the starting position. As soon as the lace guide cap 8 is rotated together with the parts arranged therein, the pin slide 30 is displaced outwards by the cam 29 until the stop surface 40 falls in outside the edge of the disk 38. While the stop surface and the edge of the disk slide against each other, and while the disk is turned from the one in fig. 5 showed an inclined position to that in fig. 4 shown horizontal position, the pin slide 30 gets an additional displacement outwards, so that its inner end is removed Æra the cam 29. During continued rotation of the sleeve 8, the inner end of the pin slide will therefore never touch the cam 29 or the hub 6. In the embodiment according to fig. 6 and 7, the spindle 12 (together with fig. 1) with an extended central pin 42 is firmly connected to a in the same way as in fig. 1 performed brake shoe 15 with support disk 14. A spring 13 affects the spindle downwards. The center pin 42 is displaceably and rotatably guided in an extended hub sleeve 43, for the cord guide sleeve 8. The hub sleeve is firmly connected to the drive shaft 5 for the sleeve 8. Stiftsleiden, which, in the manner described above, at its outer end carries the pin that can be pushed out through the cord guide cap 8 and which is influenced radially inwards by a lamellar spring 26, consists of an arm 44, the inner end of which protrudes into a radial slot 45 1 the cord guide cap 8's hub sleeve 43. The the central pin 42 guided and stored in the hub sleeve 43 is provided with an annular groove 46, the upper edge of which, through an upwardly conically widened transition surface 47, joins the semicircular pin's cylindrical outer lap. The inner end of the arm 44 is provided on the underside with a radially inward-facing ledge 48. In the normal winding position, i.e. l the push-out style of the pin 16 which is shown in fig. 6, the inner end of the arm 44 rests against the conical surface 47 on the center pin 42 and is prevented from moving further downwards by contact with the lower end of the slot 45. In this position, the landing 48 is on the underside of the arm 44 outside the working area of the cam 29 When the spindle 12 with the center pin 42, the disc 14 and the brake shoe 15 is shifted upwards, the groove 46 first positions itself in the extension of the arm 44, so that the arm of the spring 26 is pushed with its inner end into the groove 46.

With continued upward displacement of the center pin 42, the inner end of the arm 44 is brought upwards. As the inner end of the arm always protrudes a short distance inside the hub sleeve 43, this function cannot be prevented by the cam 29 possibly being in the way of the inward movement of the attachment 48. The inner end of the arm

■will under all circumstances be lifted up, so that the ledge is free from the cam and the arm 44 can be moved all the way into the slot 46. The pin 16 is then retracted. within the 8 outer periphery of the lace guide jacket. When the spindle 12, and thus the center pin 42, the disc 14 and the brake shoe

15 is released downwards under the influence of

the spring 13, the inner end is carried off

the arm again downwards, until the underside of the inner end of the arm within the landing 48 rests against the lower end of the slot 45, as shown in fig. 7, or until the lower side of the arm 44 outside the landing 48 rests against the upper side of the cam 29. The central pin 42 with the disc 14 still has a short distance left to the one in fig. 6 shown initial position, during which the upper side of the groove 46 rests against the upper side of the inner end

of the arm 44. This condition persists and the pin 16 remains retracted until the sleeve 8 is rotated by means of the shaft 5. Then the cam 29 will affect the landing 48 radially outwards until the upper edge of the

inner end of the arm 44 reaches the lower edge of the conical surface 47. Then the pin 42 is released for displacement downwards to the starting position under the influence of the spring 13, during which the conical surface 47 gives the inner end of the arm an additional displacement outwards, whereby the landing 48 is removed from the cam 29. The cap can now be turned around without the pin guide arm 44 with the ledge 48 or in any other way coming into contact with the cam 29 or the hub 6.

Claims (10)

1. Device for reel reels, with a line spool fixed in a stand, a line guide cap rotatable in the stand, but not axially displaceable, a line guide pin that can be pushed out of the cap and retracted into the cap, a pin side that carries the pin and is controlled radially 1 the interior of the string guide casing and which is actuated radially inwards by a spring, a release means which can be actuated from the outside of the reel, so that it is displaced axially against the action of a return spring from a rest position in which the release means normally holds the pin slide in an extended position, and to a release position in which the pin slide can freely move radially inwards with the help of the spring, as well as a 1 rack fixed cam for pushing back the pin slide when the line guide cap rotates to wind the line on the spool, characterized in that the pin slide (18, 30, 44) can also be swung around the hole in the line guide cap (8) in the axial plane of the reel and that the release device (14, 33, 42) is f provided with a part (14A, 38, 46) interacting with the pin slide (18, 30, 44) which, when the release device (14, 33, 42) returns to its rest position under spring action (13, resp. 39) pivots the inner end of the pin slide (18, 30, 44) within the operating area of the ejection cam. 2. Device as stated in claim 1, characterized in that the pin slide is provided with a stop surface facing radially inwards towards the reel shaft (22, 40, 41) and an axially no adjacent up-facing stop surface, while those with the release device (14 . the axially facing surfaces, after the release device (14, 33, 42) has been displaced ak cially outwards (upwards) and that the pin slide (18, 30, 44) is thereby displaced inwards during the release mechanism's return, cooperates to rotate the inner end of the pin slide axially inwards (downwards) 1 the operating area of the extension cam (29). 3. Device as stated in claim 2, characterized in that the radially facing surface or both radially facing surfaces (22, 40, 47) of the release member or the pin slide have an inclination radially beyond 1 in relation to the displacement of the release member when returning to the rest position so that the inner end of the pin slide at the end of this decline is removed from the extension cam (29). 4. Device as indicated in one of the claims 1-3, characterized in that the release means consists of an axially displaceable part (14) on the upper side of the lace guide cap and in relation to this, which cooperates with its periphery (14A) with a projection (21 ) on the pin slide which forms the stop surfaces, which protrusion protrudes from the lace guide cap (8) through a recess (23) in this. 5. Device as stated in claims 1-3, characterized in that the release means is constituted by an axially displaceable part (33) on the upper side of the lace guide cap (8) in relation to this axially displaceable part, which is provided with one or more 1 openings in the lace guide cap axially protruding pins (35) which extend through the pin slide, resp. the pin slides (30) and which have a lower flange (37) which interacts with the underside of the slide to turn the inner end of the slide over the cam (29) when the release member is displaced axially upwards, whereby a flange (38) situated above the slide cooperates with the upper side of the slide and the contact surfaces (40) placed on this. 6. Device as stated in claim 5, characterized in that the upper flange on the pin (35) consists of a disc (38) embedded in the pin, which is influenced downwards by a spring (39) to abut against the upper side of the pin slide (30). 7. Device as stated in one of the claims 4-6, characterized in that the release means consists of a disk (14, 33) on which a brake shoe (15, 34) cooperating with the inner side of an outer cap (9) for the reel is fixed ). 8. Device as stated in one of the claims 1-3, characterized in that the pin slide (44) with a tapered inner end protrudes into an axial slot (45) in the hub (43) of the lace guide cap (8) in the rest is axial displaceable property which a central pin (42) carried out, and provided with a peripheral groove (46) release means, which by axial displacement upwards brings the groove (46) to the middle of the inner end of the pin slide (44), under which this is displaced radially inwards, and then of the slot (46) is turned axially upwards together with a ledge (48) which is located on the underside of the slide, and which is intended for interaction with the cam (29), so that the ledge comes out of the operating area of the cam. 9. Device as specified in one of the stands 1-8, characterized by that the string guide pin (16) consists of a pin sleeve protruding through a hole in the string guide jacket, which is exchangeably threaded onto a guide pin formed on the outermost part of the string guide slide. 10. Device as stated in claim 9, characterized in that the pin sleeve (16) on the inner end has an outer flange (25) which forms abutment for a lamellar spring (26) which affects the pin slide inwards.