Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B27—WORKING OR PRESERVING WOOD OR SIMILAR MATERIAL; NAILING OR STAPLING MACHINES IN GENERAL
  • B27B—SAWS FOR WOOD OR SIMILAR MATERIAL; COMPONENTS OR ACCESSORIES THEREFOR
  • B27B17/00—Chain saws; Equipment therefor
  • B27B17/14—Arrangements for stretching the chain saw
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B27—WORKING OR PRESERVING WOOD OR SIMILAR MATERIAL; NAILING OR STAPLING MACHINES IN GENERAL
  • B27B—SAWS FOR WOOD OR SIMILAR MATERIAL; COMPONENTS OR ACCESSORIES THEREFOR
  • B27B17/00—Chain saws; Equipment therefor
  • B27B17/02—Chain saws equipped with guide bar
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B27—WORKING OR PRESERVING WOOD OR SIMILAR MATERIAL; NAILING OR STAPLING MACHINES IN GENERAL
  • B27B—SAWS FOR WOOD OR SIMILAR MATERIAL; COMPONENTS OR ACCESSORIES THEREFOR
  • B27B17/00—Chain saws; Equipment therefor
  • B27B17/14—Arrangements for stretching the chain saw
  • B27B17/142—Arrangements for stretching the chain saw with adjustment by at least one cam
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B27—WORKING OR PRESERVING WOOD OR SIMILAR MATERIAL; NAILING OR STAPLING MACHINES IN GENERAL
  • B27G—ACCESSORY MACHINES OR APPARATUS FOR WORKING WOOD OR SIMILAR MATERIALS; TOOLS FOR WORKING WOOD OR SIMILAR MATERIALS; SAFETY DEVICES FOR WOOD WORKING MACHINES OR TOOLS
  • B27G19/00—Safety guards or devices specially adapted for wood saws; Auxiliary devices facilitating proper operation of wood saws
  • B27G19/003—Safety guards or devices specially adapted for wood saws; Auxiliary devices facilitating proper operation of wood saws for chain saws

Definitions

• the invention relates to a portable work device. Furthermore, the invention relates to a method for operating a work device.
• Portable tools comprise a housing and a drive motor arranged within the housing, the drive motor driving a saw chain rotating on a guide bar.
• Such tools comprise a fixing device for attaching the guide bar to the housing and a tensioning device for tensioning the saw chain.
• the fixing device When the fixing device is released, the guide bar can be displaced relative to the housing in the direction of its longitudinal center axis.
• the fixing device When the fixing device is released, the saw chain can be tensioned by the tensioning device.
• the fixing device is then transferred to a fixed state. In this fixed state, the guide bar can no longer be moved relative to the housing.
• the tool is ready for use.
• a tool can be, for example, a power chainsaw, a pole pruner, or a wood cutter.
• a portable tool comprising a housing, a drive motor arranged in the housing, a guide bar with a longitudinal central axis, and a saw chain, wherein the drive motor drives the saw chain, which is guided in a guide groove of the guide bar, via a drive sprocket, in a rotating manner, a fixing device for fastening the guide bar to the housing, and a tensioning device for tensioning the saw chain.
• the guide bar In a released state of the fixing device, the guide bar is displaceable relative to the housing in the direction of its longitudinal central axis, and in a fixed state of the fixing device, the guide bar is clamped to the housing.
• the tensioning device comprises a spring unit and a release unit.
• the release unit is designed such that in the released state of the fixing device, the spring unit is operatively connected to the guide bar in an unactuated, first position of the release unit to tension the saw chain, and in an actuated, second position of the release unit, the operative connection between the spring unit and the guide bar is prevented by the release unit to release the saw chain tension.
• the tensioning device comprises an actuating element for actuating the unclamping unit and a connecting shaft, wherein the unclamping unit and the actuating element are operatively connected to one another by the connecting shaft.
• the portable working device comprises a housing, a drive motor arranged in the housing, a guide bar with a longitudinal central axis and a saw chain, wherein the drive motor drives the saw chain, which is guided in a guide groove of the guide bar, via a drive sprocket.
• the The work tool comprises a fixing device for fastening the guide bar to the housing and a tensioning device for tensioning the saw chain.
• the tensioning device comprises a spring unit and a release unit.
• the release unit is designed such that, when the fixing device is released, the spring unit is operatively connected to the guide bar in an unactuated, first position of the release unit to tension the saw chain, and when the release unit is actuated, the operative connection between the spring unit and the guide bar is prevented by the release unit to release the saw chain tension.
• the tensioning device comprises an actuating element for actuating the release unit and a connecting shaft, the release unit and the actuating element being operatively connected to one another by the connecting shaft.
• the operator To tension the saw chain of the implement, the operator must first release the locking device. In this released state, the guide bar can be moved relative to the housing in the direction of its longitudinal center axis. If the tensioning unit is now in the unactuated position, the spring unit acts on the guide bar and moves it, so that the saw chain is tensioned. Thus, tensioning of the saw chain takes place automatically as soon as the operator has released the locking device. No intervention by the operator is required.
• the spring unit acts on the guide bar with an essentially reproducible, constant force, so that the saw chain can be repeatedly tensioned with almost the same tension.
• the locking device To complete the tensioning process of the saw chain, the locking device must be returned to a fastened state.
• the tensioning process of the saw chain of the implement according to the invention described above does not require any further operations, thus preventing incorrect operation when tensioning the Saw chain, which can lead to excessive or insufficient tension of the saw chain, should be avoided.
• the active connection between the spring unit and the guide bar can also be broken by activating the release unit. If the locking device is released, no force acts on the guide bar after activating the release unit. The saw chain is no longer under tension. Maintenance work on the saw chain, guide bar, or other components can now be easily performed. This makes it particularly easy to replace the saw chain and/or guide bar of the implement, for example.
• the tensioning device comprises a connecting shaft that operatively connects the actuating element for actuating the unclamping unit and the actuating element
• the actuating element is spatially decoupled from the unclamping unit.
• the actuating element is arranged in such a way that it offers particularly user-friendly accessibility, at least when the sprocket cover is removed.
• the actuating element is designed as a pivoting lever.
• a pivoting lever is easy to operate, especially when wearing protective gloves.
• the actuating element is preloaded by a spring element, in particular a torsion spring. This preloads the actuating element into its initial position. When the operator operates the actuating element, the necessary effort to overcome the spring force of the spring element appears to be of high quality.
• the actuating element is arranged on the housing in such a way that the actuating element is accessible to the operator when the fixing device is released and is concealed by the fixing device when the fixing device is fixed. Accordingly, operation of the actuating element when the fixing device is fixed is The locking device is not possible. The operator can only operate the actuating element when the locking device is also released. This prevents incorrect operation of the actuating element.
• the actuating element is located below the guide bar.
• the guide bar has a bottom and a top side.
• the saw chain runs towards the drive motor, meaning the saw chain's running direction is towards the drive motor.
• the saw chain runs away from the drive motor, meaning the saw chain's running direction is away from the drive motor.
• the release unit comprises an eccentric.
• the eccentric is operatively connected to the actuating element, in particular via the connecting shaft.
• the spring unit acts on a carriage movable in the direction of the longitudinal center axis of the guide rail, wherein the carriage is operatively connected to the guide rail in the direction of the longitudinal center axis.
• the carriage is connected to the guide rail in such a way that when the carriage moves in the direction of the longitudinal center axis of the guide rail, the carriage moves with it.
• a driver pin is formed on the carriage, which engages in an opening in the guide rail.
• the carriage and the guide rail are connected to one another in the direction of the longitudinal center axis of the guide rail, in particular in a form-fitting manner.
• the eccentric is designed so that it is not in contact with the carriage in the first position of the unclamping unit, and acts directly on the carriage in the second position of the unclamping unit.
• the eccentric is designed such that when the unclamping unit is switched from the first position to the second position, the eccentric causes the guide rail to move in the direction of the longitudinal center axis, counteracting a spring force emanating from the spring unit.
• the spring unit acts in particular on the carriage. In the second position of the unclamping unit, the eccentric acts on the carriage and thus counteracts the spring force of the spring unit. The spring force is neutralized by the eccentric, as a result of which the saw chain is no longer tensioned.
• the eccentric and the slide are designed in such a way that the eccentric locks onto the slide in the second position of the release unit. Once the eccentric is locked, the operator can easily perform maintenance work on the tool.
• a partition be provided between the guide bar and the tensioning device to protect the tensioning device from dirt particles emanating from the saw chain.
• the partition between the guide bar and the tensioning device prevents the transfer of dirt particles, such as chips, oil, etc., from the saw chain to the tensioning device.
• the tensioning device is thus protected from contamination, ensuring easy and reliable operation of the tensioning device over the long term.
• FIG. 1 An embodiment of a working device 1 according to the invention is shown.
• the portable, in particular hand-carried, working device 1 is designed in the exemplary embodiment as a wood cutter.
• a wood cutter is a motor-driven working device intended in particular for cutting branches and small woody plants.
• the preferred use of a wood cutter is, in particular, the limbing of trees.
• the working device 1 can also be designed as a chainsaw or the like.
• the working device 1 can also be designed as a working device with a shaft, for example, as a pole pruner or the like.
• the term "portable" is to be understood in such a way that the working device is carried by the operator during its intended use.
• the working device 1 comprises a housing 2.
• the working device 1 comprises a drive motor 3.
• the drive motor 3 is in Fig. 1 represented only schematically by a dashed line.
• the drive motor 3 is arranged in the housing 2.
• the working device 1 further comprises a tool 6, wherein the tool 6 is driven by the drive motor 3.
• the tool 6 is a saw chain.
• the saw chain is driven in rotation in a guide groove of a guide rail 4.
• the drive motor 3 drives a drive sprocket via its drive shaft. 9 ( Fig. 3 ), which in turn drives the saw chain 6 to rotate around the guide bar 4.
• a pivoting hood 18 is arranged on the housing 2. The hood 18 engages over the top of the guide bar 4 and thus also the tool 6. When sawing through the material to be cut with the incoming chain, the hood 18 pivots upward.
• the drive motor 3 is designed as an electric motor in the exemplary embodiment.
• the working device 1 comprises at least one battery pack 11, 12 for supplying the drive motor 3 with electrical energy.
• this comprises a first battery pack 11.
• the first battery pack 11 is provided for supplying the drive motor 3 with electrical energy.
• the working device 1 comprises, in particular, a second battery pack 12.
• the second battery pack 12 is also provided for supplying the drive motor 3 with electrical energy.
• the working device 1, in particular the drive motor 3 of the working device 1 can in particular also be operated using just one of the two battery packs 11, 12.
• the two battery packs are connected in series.
• the two battery packs 11, 12 and a rear end 46 of the working device 1 are only shown schematically by dashed lines.
• the drive motor 3 can also be designed as an internal combustion engine.
• the guide rail 4 comprises a longitudinal central axis 5.
• the working device 1 comprises a longitudinal plane 43 which is spanned by the guide groove of the guide rail 4.
• the longitudinal central axis 5 of the guide rail 4 lies in the longitudinal plane 43.
• the longitudinal central axis 5 runs centrally through the guide rail 4, whereby the guide rail 4 is divided into two approximately equal parts by the longitudinal central axis 5 when viewed perpendicular to the longitudinal plane 43 of the guide rail 4.
• the guide rail 4 comprises a transverse plane 44.
• the transverse plane 44 is aligned orthogonally to the longitudinal plane 43 of the guide rail 4.
• the longitudinal central axis 5 lies in the transverse plane 44.
• the housing 2 of the working device 1 comprises a front end 45 and a rear end 46.
• the guide rail 4 is fastened to the housing 2 and protrudes from the housing 2 at the front end 45 of the housing 2.
• the rear end 46 of the housing 2 is formed in the present embodiment by a receiving section 13.
• the first battery pack 11 and the second battery pack 12 are held on the receiving section 13.
• the two battery packs 11, 12 are detachably held in the receiving section 13.
• the rear end 46 can also be formed by a handle of the working device 1.
• the working device 1 comprises a first handle 47 for supporting a hand of the operator.
• the first handle 47 is formed on a handle housing 49.
• the handle housing 49 is part of the housing 2.
• the working device 1 comprises a control element 50 for actuating the drive motor 3.
• the control element 50 is assigned to the first handle 47, i.e. during normal operation of the working device 1, the operator actuates the control element 50 with the hand that rests on the first handle 47.
• the control element 50 is designed in particular as a control lever.
• the handle 47 is preferably designed such that it can be grasped by the operator with one hand. This allows the operator to hold, in particular carry, the working device 1 by the handle 47.
• the working device 1 comprises a locking element 51, wherein the locking element 51 is designed in particular as a mechanical locking element 51.
• the locking element 51 is preferably designed as a locking lever.
• the locking element 51 is designed to lock the control element 50 in a locked position, in particular mechanically, and to release it in an operating position. If the operator wishes to actuate the control element 50, they must first unlock the control element 50 by actuating the locking element 51. The operator can then actuate the control element 50 and control the drive motor 3.
• the working device 1 comprises a second handle 48.
• the second handle 48 serves to support the operator's second hand and enables the operator to better guide the working device 1.
• the second handle 48 is provided on the housing 2, in particular in the area of the drive motor 3.
• the working device 1 comprises a fixing device 10 for securing the guide rail 4.
• the guide rail 4 In a fixed state of the fixing device 10, the guide rail 4 is clamped to the housing 2.
• the guide rail 4 In a released state of the fixing device 10, the guide rail 4 is displaceable in the direction of the longitudinal center axis 5 relative to the housing 2.
• the guide rail 4 can be pushed away from the housing 2 in the direction of its longitudinal center axis 5, whereby the saw chain 6 can be tensioned.
• the working device 1 comprises a chain wheel cover 14.
• the chain wheel cover 14 is part of the fixing device 10.
• the guide rail 4 is clamped between the chain wheel cover 14 and the housing 2.
• a nut 15 is provided for fastening the chain wheel cover 14 to the housing 2.
• the nut 15 is screwed onto a bolt 17 ( Figures 3 and 4 ), which is firmly connected to the housing 2.
• the nut 15 presses the sprocket cover 14 against the guide rail 4, and the guide rail 4 against the housing 2.
• the nut 15 comprises a pivoting lever 16, which, when in the upright position, serves to rotate the nut 15.
• the operator can tighten and loosen the nut 15 without the need for tools.
• the sprocket cover 14 covers the sprocket 9 driven by the drive motor 3.
• the working device 1 comprises a tensioning device 20.
• the tensioning device 20 is designed to tension the saw chain 6.
• the guide rail 4 is displaceable in the direction of its longitudinal center axis 5 relative to the housing 2.
• the tensioning device 10 can act on the guide rail 4 in such a way that the guide rail 4 is pushed forward, i.e., in the direction of the longitudinal center axis 5 of the guide rail 4, away from the front end 45 of the housing 2. This tensions the saw chain 6, which rests on the guide rail.
• the tensioning device 20 comprises a spring unit 26, a carriage 23 and a release unit 21.
• the spring unit 26 is supported at one end on the housing 2 and acts with its other end against the carriage 23.
• the carriage 23 is held on the housing 2 so that it can move in the direction of the longitudinal center axis 5 of the guide rail 4.
• the carriage 23 is in particular directly operatively connected to the guide rail 4.
• the carriage 23 comprises a driver pin 28.
• the driver pin 28 projects into an opening 29 in the guide rail 4.
• the driver pin 28 is aligned in its longitudinal direction approximately vertically to the longitudinal plane 43. In the direction of movement of the guide rail 4, the driver pin 28 and the guide rail 4 are positively connected to one another.
• the carriage 23 if the carriage 23 is pushed via the spring unit 26 in the direction of the longitudinal center axis 5 of the guide rail 4, the carriage 23 carries the guide rail 4 along via the drive pin 28.
• the saw chain 6 is tensioned by means of the spring force of the spring unit 26.
• the spring unit 26 is formed from a helical spring.
• the spring unit 26 can be formed from a different type of spring and/or from multiple springs.
• a pin 35 is formed on the carriage 23, on which the spring unit 26, in particular the helical spring, is received.
• the release unit 21 has an unactuated, first position 41 and an actuated, second position 42.
• the release unit 21 is designed such that in the released state of the fixing device 10, the spring unit 26 in the first position 41 of the The tension release unit 21 is operatively connected to the guide bar 4 for tensioning the saw chain 6, and in an actuated, second position 42 of the tension release unit 21, the operative connection between the spring unit 26 and the guide bar 4 is prevented by the tension release unit 21 to release the saw chain tension.
• the tension release unit 21 counteracts the spring force of the spring unit 26 and thereby releases the tension of the saw chain 6 by displacing the guide bar 4 backward along the longitudinal center axis 5 of the guide bar 4.
• the clamping device 20 comprises an actuating element 22 for switching the unclamping unit 21 into the first position 41 or into the second position 42. Furthermore, the clamping device 20 comprises a connecting shaft 27.
• the unclamping unit 21 and the actuating element 22 are operatively connected to one another via the connecting shaft 27.
• the connecting shaft 27 is rotatably mounted in the housing 2 about an axis of rotation 36.
• the axis of rotation 36 of the connecting shaft 27 is aligned in particular perpendicular to the transverse plane 44.
• the connecting shaft 27 extends along its axis of rotation 36 from a first end 37 to a second end 38.
• the unclamping unit 21 is arranged at the first end 37 of the connecting shaft 27.
• the actuating element 22 is arranged at the second end 38 of the connecting shaft 27.
• the unclamping unit 21 and the actuating element 22 are mechanically connected to one another via the connecting shaft 27.
• the release unit 21, the connecting shaft 27, and the actuating element 22 can be constructed as a single piece, for example, as a cast part, particularly as an injection-molded part, or as a multi-part assembly. If the components are constructed as multi-part components, they are, of course, firmly connected to one another.
• the actuating element 22 is designed as a pivoting lever.
• the pivoting lever like the connecting shaft 27, is pivotable about the rotational axis 36.
• the clamping unit 21 also includes a spring element 25, which is provided for preloading the actuating element 22.
• the spring element 25 is designed in particular as a torsion spring.
• the spring element 25 acts on the connecting shaft 27 and/or on the actuating element 22 such that the actuating element 22 is preloaded into the unactuated position 41 of the unclamping unit 21. If the operator wishes to switch the unclamping unit 21 to the second position 42 via the actuating element 22, he or she must overcome not only the spring force of the spring unit 25 but also the spring force of the spring element 25.
• the spring element 25 is preferably arranged at the second end 38 of the connecting shaft 27 and acts there directly as a torsion spring on the end 38 of the connecting shaft 27.
• the spring element 25 is supported on the housing 2.
• the spring element 25 is guided on a pin 61.
• the pin 61 is arranged on the connecting shaft 27.
• the pin 61 and the connecting shaft 27 form a base body 60, which can in particular be formed as a single piece.
• the base body 60 is in particular cast.
• An extension 62 is formed on the second end 38 of the connecting shaft 27. The extension 62 engages over the spring element 25, as a result of which the spring element 25 is at least partially guided by the extension 62.
• the extension 62 is designed as a wall section bent around the axis of rotation 36 of the connecting shaft 27.
• the extension 62 extends in the direction of the rotational axis 36 of the connecting shaft 27 over at least one turn of the spring element 25, in particular over at least two turns of the spring element 25.
• the extension 62' is cylindrical.
• the alternative extension 62' is in Fig. 7 shown in dashed lines.
• the extension 62' essentially encompasses the spring element 25 in the circumferential direction of the rotational axis 36 of the connecting shaft 27.
• An opening, in particular a groove, is provided on the extension 62', in which one end of the spring element 25 is held.
• the alternative extension 62' extends in the direction of the rotational axis 36 of the connecting shaft 27 over at least 30%, in particular over at least 40%.
• the connecting shaft 27 has a central section 64 in addition to its first end 37 and its second end 38.
• the connecting shaft 27 is pivotally mounted about the axis of rotation 36 relative to the housing 2 via its central section 64.
• the housing 2 has a holding space 65 in which the connecting shaft 27 is arranged in the housing 2.
• a first opening 66 is provided in the holding space 65, through which the central section 64 of the connecting shaft 27 projects.
• the second end 38 of the connecting shaft 27 is arranged immediately adjacent to this first opening 66.
• the first opening 66 has an inner diameter d.
• the second end 38 of the connecting shaft 27 has an outer diameter D. In the exemplary embodiment, the outer diameter D of the second end 38 of the connecting shaft 27 is larger than the inner diameter d of the first opening 66.
• the housing 2 forms a stop for the second end 38 of the connecting shaft 27 at the first opening 66.
• the contours of the second end 38 of the connecting shaft 27 and of the housing 2 at the first opening 66 form a type of labyrinth seal, whereby the space below the first opening 66, in particular the spring element 25, is protected from contamination.
• the first opening 66 forms a first bearing point for the connecting shaft 27 with the central portion 64 of the connecting shaft 27.
• a second bearing point is provided adjacent to the first end 37 of the connecting shaft 27, at which the central portion 64 of the connecting shaft 27 is mounted relative to the housing.
• the second end 38 of the connecting shaft 27 is formed by a sleeve 63. The sleeve 63 is connected to the actuating element 22.
• the release unit 21 comprises an eccentric 24.
• the eccentric 24 has a contour 39 which is designed such that when the eccentric 24 is pivoted by the actuating element 22 into the actuated position 42 of the release unit 21, the carriage 23 is pushed rearward against the spring force of the spring unit 26.
• a first active surface 52 is formed on the contour 39 of the eccentric 24, which interacts with the carriage 23, in particular with a second active surface 53 of the carriage 23, when switching to the second position 42.
• a recess 54 is formed on the second active surface 53 of the carriage 23, in which recess the eccentric 24 locks.
• a holding contour 55 is formed on the recess 54, which prevents the eccentric 24 from being pivoted back into the unactuated position 41 due to the spring force of the spring element 25.
• the eccentric 24 must be actively pivoted back by the operator via the actuating element 22. This allows the operator to lock the unclamping unit 21 in the recess 54 of the second active surface 53 of the slide 23 and, for example, to be able to carry out corresponding maintenance work on the work tool 1 without having to hold the actuating element 22 in the actuated position 42.
• the unclamping unit 21 is in the unactuated position 41, as shown in the Figures 9 and 10 As shown, the first effective surface 52 of the eccentric 24 and the second effective surface 53 of the carriage 23 do not contact each other as long as the guide rail 4 is tensioned against the saw chain 6.
• the guide rail 4 has a maximum height h, which is measured orthogonally to the transverse plane 44.
• the connecting shaft 27 has a length l measured in the direction of its rotational axis 36. The length l of the connecting shaft 27 is at least 50% of the maximum height h of the guide rail 4.
• Fig. 2 The running direction 56 of the saw chain 6 is shown.
• the saw chain 6 runs towards the chain wheel, on the top of the The saw chain runs away from the sprocket along the guide bar 4.
• the actuating element 22 is located below the guide bar 4, thus facing the underside of the guide bar 4. This makes the actuating element 22 particularly accessible and easy to operate for the operator.
• the working device 1 comprises a partition wall 7.
• the partition wall 7 is arranged between the guide rail 4 and the tensioning device 20.
• the partition wall 7 serves to protect the tensioning device 20 from dirt particles emanating from the saw chain 6.
• the housing 2 defines a housing interior 30.
• the partition wall 7 divides the housing interior 30 into a first interior 31 of the housing 2 and a second interior 32 of the housing 2.
• the guide rail 4 is arranged in the first interior 31.
• the tensioning device 20 is arranged in the second interior 32. The guide rail 4 and the tensioning device 20 are thus spatially decoupled from one another.
• the partition wall 7 comprises an opening 8.
• the carriage 23 projects through the opening 8 of the partition wall 7 with its driver pin 28 for positive connection to the guide rail 4.
• the opening 8 is designed as large as necessary to allow the carriage 23 sufficient freedom of movement in the direction of the longitudinal center axis 5 of the guide rail 4 for tensioning the saw chain 6.
• the opening 8 is designed as small as possible to ensure effective protection for the tensioning device 20 from dirt particles emanating from the saw chain 6.
• the opening 8 is designed in particular as an elongated hole.
• the opening 8 and the slide 23 are designed and arranged relative to one another in such a way that the opening 8 in the partition 7 is completely covered by the slide 23 in any position of the slide 23.
• a slide extension 70 is formed on the slide 23, which closes the opening 8 of the partition 7 towards the unclamping unit 21. Furthermore, the slide extension 70 is on the slide 23 designed such that, in the unactuated, first position of the unclamping unit 21, it abuts against the housing 2 in the direction of the longitudinal center axis 5 of the guide rail 4. Furthermore, the slide extension 70 forms a stop for the unclamping unit 21, in particular for the eccentric 24 of the unclamping unit 21.
• the slide extension 70 has a width measured perpendicular to the longitudinal plane 43 that corresponds to less than 50%, in particular less than 30%, of the total width of the slide 23 measured perpendicular to the longitudinal plane 43.
• the opening 8 has a length a measured in the direction of the longitudinal center axis 5 of the guide rail 4.
• the carriage 23, in particular the driving pin 28, has a width b measured in the longitudinal center axis 5 of the guide rail 4.
• the length a of the opening 8 corresponds to at least 1.5 times, in particular at least 2 times, in particular approximately 2.5 times the width b of the driving pin 28.
• the opening 8 corresponds to at most 5 times, in particular at most 4 times, in particular at most 3 times the width b of the driving pin 28.
• the operating procedure for working device 1 is described below: To tension the saw chain 6, the nut 15 and thus also the sprocket cover 14 must first be loosened. The locking device 10 is thereby transferred from a fixed state to a released state. If the guide bar 4 is no longer clamped between the housing 2 and the sprocket cover 14, the guide bar 4 is pushed forward via the carriage 23 by the spring force of the spring unit 26. The saw chain 6 is thereby tensioned. If the operator only wishes to tension the saw chain 6, they can now screw the sprocket cover 14 back against the guide bar 4 using the nut 15. The working device 1 is ready for operation again. The unclamping unit 21 is in the deactivated state 41.
• the operator must actuate the tensioning unit 21.
• the chain wheel cover 14 must first be removed from the housing 2.
• the sprocket cover 14 is arranged on the housing 2 in such a way that it at least partially covers the actuating element 22 of the clamping unit 20, so that the actuating element 22 cannot be pivoted. If the sprocket cover 14 is removed from the housing 2, the operator has access to the actuating element 22, as shown in the Figures 3 and 4 The release unit 21 is then in the unactuated position 41, as shown in the Figures 3, 4 , 9, 10 shown. In the unactuated position 41 of the tensioning unit 21, the carriage 23 and the tensioning unit 21 do not contact each other. The saw chain 6 is tensioned.
• the actuating element 22 is to be actuated in order to transfer the tensioning unit 21 into the second, actuated position 42.
• the eccentric 24 acts against the carriage 23, whereby the tension of the saw chain 6 is released.
• the actuating element 22 is in particular to be pivoted open until the tensioning unit 21 locks onto the carriage 23. In this position, the eccentric 24 lies with its first active surface 52 in the recess 54 of the second active surface 53 of the carriage 23 and in particular contacts the holding contour 55 of the recess 54. The operator can carry out his maintenance work on the work tool 1 with the saw chain 6 relaxed.
• the operator pivots the actuating element 22 back, moving the tensioning unit 21 from the actuated position 42 to the deactuated position 41.
• the saw chain 6 is tensioned again.
• the sprocket cover 14 can then be screwed back onto the guide bar 4 using the nut 15.

Landscapes

• Life Sciences & Earth Sciences (AREA)
• Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• Wood Science & Technology (AREA)
• Forests & Forestry (AREA)
• Sawing (AREA)

Applications Claiming Priority (2)

Publications (1)

Family

ID=94869864

Family Applications (1)

Country Status (2)

Citations (4)

• 2025
  • 2025-02-27 CN CN202510222939.0A patent/CN120552158A/zh active Pending
  • 2025-02-28 EP EP25161144.8A patent/EP4610007A1/fr active Pending

Patent Citations (4)

Also Published As

Similar Documents

Legal Events