WO2013044844A1 - 多功能机 - Google Patents
多功能机 Download PDFInfo
- Publication number
- WO2013044844A1 WO2013044844A1 PCT/CN2012/082300 CN2012082300W WO2013044844A1 WO 2013044844 A1 WO2013044844 A1 WO 2013044844A1 CN 2012082300 W CN2012082300 W CN 2012082300W WO 2013044844 A1 WO2013044844 A1 WO 2013044844A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- working head
- output shaft
- multifunction machine
- positioning
- machine according
- Prior art date
Links
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B26—HAND CUTTING TOOLS; CUTTING; SEVERING
- B26D—CUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
- B26D7/00—Details of apparatus for cutting, cutting-out, stamping-out, punching, perforating, or severing by means other than cutting
- B26D7/26—Means for mounting or adjusting the cutting member; Means for adjusting the stroke of the cutting member
- B26D7/2614—Means for mounting the cutting member
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B23/00—Portable grinding machines, e.g. hand-guided; Accessories therefor
- B24B23/04—Portable grinding machines, e.g. hand-guided; Accessories therefor with oscillating grinding tools; Accessories therefor
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B27/00—Other grinding machines or devices
- B24B27/06—Grinders for cutting-off
- B24B27/08—Grinders for cutting-off being portable
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B45/00—Means for securing grinding wheels on rotary arbors
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B25—HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
- B25F—COMBINATION OR MULTI-PURPOSE TOOLS NOT OTHERWISE PROVIDED FOR; DETAILS OR COMPONENTS OF PORTABLE POWER-DRIVEN TOOLS NOT PARTICULARLY RELATED TO THE OPERATIONS PERFORMED AND NOT OTHERWISE PROVIDED FOR
- B25F3/00—Associations of tools for different working operations with one portable power-drive means; Adapters therefor
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B26—HAND CUTTING TOOLS; CUTTING; SEVERING
- B26D—CUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
- B26D1/00—Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor
- B26D1/01—Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work
- B26D1/12—Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a cutting member moving about an axis
Definitions
- the present invention relates to a multifunction machine, and more particularly to a multifunction machine that can mount a plurality of different types of work heads.
- the multi-function machine is a hand-held swing-type power tool commonly used in the industry. Its working principle is that the output shaft makes a rotary oscillating motion around its own axis line, thereby driving the attachment working head mounted at the end of the output shaft to swing. Common attachment heads include straight saw blades, circular saw blades, triangular sanding discs, and spade scrapers. Therefore, when the user installs different accessory working heads on the output shaft, a variety of different operating functions, such as sawing, cutting, grinding, scraping, etc., can be implemented to suit different work requirements.
- a conventional multi-function machine is provided with a form-fitting mechanism for transmitting torque between the work head and the output shaft.
- a star-shaped opening with eight rounded corners is provided on the working head, and the rounded corners are continuously connected.
- the end of the output shaft is radially convexly extended with four rounded protrusions.
- the precondition for mounting the working head on the output shaft is that the star-shaped opening of the working head matches the convex shape on the output shaft, otherwise, if it is replaced with a work with other shape openings The head cannot be mounted on the output shaft. Therefore, the type of work head that allows the output shaft to be connected is limited.
- the technical problem to be solved by the present invention is to provide a multi-function machine that can connect a plurality of different types of work heads.
- a multi-functional machine comprising an output shaft for mounting a working head and driving the movement of the working head, and a fastener for mounting the working head on the output shaft
- the working head has a mounting portion connectable to the output shaft, the output shaft end having a driving portion coupled to the mounting portion of the working head, the driving portion having a contact with an upper surface of the mounting portion Friction surface.
- the invention has the beneficial effects that: the friction surface is closely matched with the upper surface of the mounting portion, so that the multi-function machine can connect different types of working heads, thereby greatly improving the versatility and convenience of the multi-function machine. Sex, and the friction between the friction surface and the upper surface of the mounting portion is sufficient. It is large enough to transmit the oscillating torque on the output shaft to the working head during the operation of the multi-function machine without causing the working head to slip.
- the multifunction machine further includes a positioning member and an elastic member, the elastic member causing the positioning member to always move axially in a direction in contact with the working head.
- the working head includes a first working head and a second working head
- the first working head includes a first central surface parallel to the mating surface and a first connecting hole through which the fastener passes
- the second working head includes a second center surface parallel to the mating surface and a second connecting hole through which the fastener passes, the positioning element being at least partially in contact with the first connecting hole and having the first center plane a first cross-section; the positioning element being at least partially in contact with the second connection aperture and having a second cross-section in the second central plane, the first cross-section being different from the second cross-section.
- the positioning element can form different cross sections on the corresponding central surface when contacting the first or second working head, so that the positioning element can be adapted With a variety of different types of work heads.
- an outer contour of the first cross section forms a first circumscribed circle
- an outer contour of the second cross section forms a second circumscribed circle, wherein a diameter of the first circumscribed circle and the second circumscribed circle Not the same.
- the shape of the first cross section and the shape of the second cross section are different.
- the positions of the first cross section and the second cross section are different from each other with respect to the output shaft.
- the shape of the first and second cross sections is at least one of a circle, a polygon or an ellipse.
- the positioning element includes a central hole through which the fastener passes and an outer peripheral surface disposed around the central hole, the outer peripheral surface including an axially disposed first outer contour that is in contact with the first connecting hole and a second outer contour that is in contact with the second connection hole.
- the outer peripheral surface includes at least one conical surface, and the first outer contour and the second outer contour are disposed on the conical surface.
- the outer peripheral surface includes at least a first cylindrical surface and a second cylindrical surface, and the first outer contour is disposed on the first cylindrical surface, and the second outer contour is on the second cylindrical surface.
- the first cylindrical surface and the second cylindrical surface are axially intermittently disposed or axially continuous.
- the change in the maximum radial dimension of the outer peripheral surface from the first outer contour to the second outer contour is linear.
- the change in the maximum radial dimension of the outer peripheral surface from the first outer contour to the second outer contour is non-linear.
- the outer peripheral surface intersects with a longitudinal section passing through a center line of the center hole to form an intersection line,
- the intersection line is at least one of a straight line, a curve or an arc.
- the positioning component is a deforming member, and the deforming member is in contact with the first connecting hole and forms a first circumscribed circle tangential to the first connecting hole in the first central plane;
- the second connection holes are in contact with each other and form a second circumscribed circle tangential to the second connection hole in the second center plane.
- the positioning element includes a mating portion for transmitting torque on the output shaft to the working head, and an adapter portion mated with the working head.
- the adapter portion includes at least a first adapter portion and a second adapter portion that are mated with connection holes of different shapes.
- the positioning component comprises a disc-shaped body, and the forming portion is formed by radially outwardly extending from an outer circumference of the disc-shaped body, and the first and second adapter portions are One side of the disc-shaped body is axially protruded.
- the shaped portion includes at least two shaped elements extending radially from the outer circumference of the disc-shaped body.
- the projection of the outer contour of the disc-shaped body on a plane perpendicular to the output axis is a polygon.
- the second adapter portion is disposed on one side of the first adapter portion in the axial direction, and the first adapter portion and the second adapter portion have different radial dimensions.
- the first adapter portion and the second adapter portion have different projection shapes on a plane perpendicular to the output shaft.
- the outer contour of at least one of the first adapter portion and the second adapter portion is a male or a cylindrical surface.
- the projection of the outer contour of the first adapter portion on a plane perpendicular to the output shaft is a regular polygon
- the second adapter portion includes at least two protrusions extending axially from the first adapter portion.
- the positioning component further includes a third adapter portion disposed axially with respect to the first adapter portion and the second adapter portion, wherein the third adapter portion has a radial dimension smaller than the first The radial dimension of the adapter or the second adapter.
- the outer contour of the third adapter portion is a conical surface or a cylindrical surface.
- the fastener includes a pressure plate in contact with the working head, and the elastic member is disposed between the pressure plate and the positioning member.
- the fastener includes a pressing plate that is in contact with the working head, and the pressing plate is provided with a matching portion adapted to the forming portion, the elastic member is disposed on the pressing plate and the Locating between components.
- the fastener is provided with a stop ring that stops the positioning element from being axially disengaged.
- the positioning element is disposed in the output shaft, and the elastic element is disposed between the output shaft and the positioning element.
- the output shaft is provided with a fitting portion adapted to the fitting portion, and the elastic member is disposed between the output shaft and the positioning member.
- the output shaft is provided with a stop for stopping the axial disengagement of the positioning element.
- the multifunction machine includes a positioning member and an elastic member that urges the positioning member to always move radially toward a direction in which the first or second connection holes of the working head are in contact.
- the working head includes a first working head and a second working head
- the first working head includes a first central surface parallel to the mating surface and a first connecting hole through which the fastener passes
- the second working head includes a second central surface parallel to the mating surface and a second connecting hole through which the fastener passes
- the positioning element comprising at least two circumferentially disposed positioning blocks, the at least two positioning blocks and the second a connecting hole is in contact and a first cross section is defined on the first central surface; the at least two positioning blocks are in contact with the second connecting hole and a second cross section is defined in the second central surface, The positions of the first cross section and the second cross section are different from the output shaft.
- the friction surface is mainly formed by a plurality of convex ribs.
- the ribs extend radially with respect to an axis of the output shaft.
- the friction surface is formed by a plurality of axially protruding mandrels.
- the mandrel is conical or annular.
- the friction surface comprises a coating layer comprising a friction material.
- the coating layer is mainly composed of a metal material.
- the driving portion is provided with a recess
- the multifunction machine further includes a centering element that cooperates with the recess.
- the centering element includes a first surface, a second surface opposite to the first surface, a peripheral wall connecting the first surface and the second surface, and a central positioning hole through which the fastener passes, the second surface A fitting portion that cooperates with the mounting portion is provided.
- the first surface is a plane.
- the centering element is made of plastic or a metal material.
- the centering element is provided with an expansion hole which is circumferentially hooked.
- the forming portion includes a boss extending axially from the second surface around the central positioning hole, and the outer side wall of the boss is a regular polygon or a regular polygon.
- the forming portion includes at least three protrusions extending axially from the second surface and uniformly disposed in a circumferential direction, the protrusion being a circle extending radially outward from the center positioning hole Shaped tip.
- the forming portion comprises at least three locking elements, the locking element extending axially from the second surface and being circumferentially hooked, the locking element being located outside the central positioning hole.
- the locking element has a cross section of any one of a trapezoidal shape, a rectangular shape, a triangular shape, an arc shape, a square shape, a circular shape or an elliptical shape.
- a centering element for a multi-function machine comprising an output shaft for driving a rotary swing of the working head, and a fastener for mounting the working head on the output shaft, the working head having a connectable to a mounting portion of the output shaft, wherein the output shaft end is provided with a driving portion that is coupled to the mounting portion of the working head, the driving portion has a friction surface that is in contact with the upper surface of the mounting portion, and the centering portion a component-fitted recess, characterized in that: the centering element comprises a first face, a second face opposite the first face, a peripheral wall connecting the first face and the second face, and a central positioning hole through which the fastener passes The second surface is provided with a forming portion extending axially and engaging the mounting portion, and a maximum distance between the first surface and the second surface is not greater than an axial depth of the recess.
- the centering element can use a relatively low cost material to design a corresponding centering element based on the working head having various mounting portions. Therefore, in the case where the multifunction machine can be matched with various types of work heads, there is no increase in cost.
- a fastening device for assembling a plurality of working heads to a multi-function machine comprising an output shaft for mounting a working head and driving a rotary swing of the working head, the output shaft comprising a working head a mating mating surface;
- the working head includes at least a first working head and a second working head, wherein the first working head includes a first mounting portion that is mated with the output shaft, and the first mounting portion includes a mating surface a first first central surface parallel to the first connecting hole through which the fastener passes;
- the second working head includes a second mounting portion that mates with the output shaft, the second mounting portion including the second parallel to the mating surface a second center face and a second connecting hole through which the fastener passes,
- the fastening device comprising a fastener coupled to the output shaft, a positioning member disposed on the fastener, wherein the positioning member is capable of The first attachment aperture is at least partially in contact and has a first cross-section in the first central plane; the positioning element
- the fastening device is provided with a positioning element, which can form different cross sections on the corresponding central surface when contacting the first or second working head, so that the positioning element can be adapted to a plurality of different Type of work head.
- the positioning element for positioning is provided, The advantageous separation of the positioning function from the fixed function and/or the transfer torque reduces the wear of the positioning element.
- the positioning component is a deforming member, and the deforming member is in contact with the first connecting hole and forms a first circumscribed circle tangential to the first connecting hole in the first central plane;
- the second connection holes are in contact with each other and form a second circumscribed circle tangential to the second connection hole in the second center plane.
- the multi-function machine further includes an elastic member that urges the positioning member to always move axially in a direction in contact with the first connecting hole or the second connecting hole, and the fastener includes contacting the working head a pressure plate, the elastic member being disposed between the pressure plate and the positioning member.
- FIG. 1 is a schematic view showing a head region and a part of a casing removed in a first embodiment of the multifunction machine of the present invention.
- Fig. 2 is a perspective exploded perspective view showing the head region and a part of the outer casing removed in the first embodiment of the multifunction machine of the present invention.
- Figure 3 is a schematic view of a friction surface in a first embodiment of the multifunction machine of the present invention.
- Fig. 4 is a cross-sectional view showing the first embodiment of the multifunction machine of the present invention in which the working head is mounted on the friction surface shown in Fig. 3.
- Fig. 5 is a perspective exploded perspective view showing the first embodiment of the multifunction machine of the present invention in which the working head is engaged with another friction surface.
- Figure 6 is a schematic view of the friction surface shown in Figure 5.
- Fig. 7 is a perspective exploded perspective view showing the working head in cooperation with another friction surface in the first embodiment of the multifunction machine of the present invention.
- Figure 8 is a schematic view of the friction surface shown in Figure 7.
- Figure 9 is a cross-sectional view taken along line A-A of Figure 7.
- Figure 10 is an enlarged view of B in Figure 9.
- Fig. 11 is a perspective exploded perspective view showing the first embodiment of the multifunction machine of the present invention in which the working head is engaged with another friction surface.
- Fig. 12 is a perspective exploded perspective view showing the working head, the output shaft, and the centering member in the second embodiment of the multifunction machine of the present invention.
- Fig. 13 is a perspective exploded perspective view showing the working head, the output shaft, and the centering member in the second embodiment of the multifunction machine of the present invention, wherein the centering member is housed in the recess of the output shaft.
- Figure 14 is a schematic illustration of the first side of the centering element shown in Figure 12.
- Figure 15 is a side elevational view of the centering element shown in Figure 12.
- Figure 16 is a schematic illustration of the second side of the centering element shown in Figure 12.
- Figure 17 is a cross-sectional view showing the second embodiment of the multifunction machine of the present invention in which the working head is mounted on the output shaft by the centering member.
- Fig. 18 is a perspective exploded perspective view showing the working head, the output shaft, and the centering member in the third embodiment of the multifunction machine of the present invention.
- Figure 19 is a schematic illustration of the first side of the centering element shown in Figure 18.
- Figure 20 is a side elevational view of the centering element shown in Figure 18.
- Figure 21 is a schematic illustration of the second side of the centering element shown in Figure 18.
- Fig. 22 is a perspective exploded perspective view showing the working head, the output shaft, and the centering member in the fourth embodiment of the multifunction machine of the present invention.
- Figure 23 is a schematic illustration of the first side of the centering element shown in Figure 22.
- Figure 24 is a side elevational view of the centering element shown in Figure 22.
- Figure 25 is a schematic illustration of the second side of the centering element shown in Figure 22.
- Figure 26 is a perspective exploded perspective view showing the head region of the multi-function machine in the fifth embodiment of the present invention.
- Figure 27 is a perspective view of a first working head suitable for use in the multifunction machine of Figure 26.
- Figure 28 is a perspective view of a second working head suitable for use in the multifunction machine of Figure 26.
- Figure 29 is a perspective view of a third working head suitable for use in the multifunction machine of Figure 26.
- Figure 30 is a perspective view of a fourth working head suitable for use in the multifunction machine of Figure 26.
- Figure 31 is a perspective view showing the positioning member of the fifth embodiment of the multifunction machine of the present invention.
- Figure 32 is a front elevational view of the positioning member of Figure 31.
- Figure 33 is a perspective view showing the first working head shown in Figure 27 mated with the positioning member.
- Figure 34 is a perspective view of the second working head shown in Figure 28 mated with the positioning member.
- Figure 35 is a perspective view of the third working head shown in Figure 29 mated with the positioning member.
- Figure 36 is a perspective view showing the engagement of the fourth working head shown in Figure 30 with the positioning member.
- Figure 37 is a perspective exploded perspective view showing another angle of the head region of the multifunction machine shown in Figure 26.
- Figure 38 is a cross-sectional view showing the head region of the multifunction machine of Figure 26, in which the fastener and the first working head are not yet mounted on the output shaft.
- Figure 39 is a cross-sectional view showing the head region of the multifunction machine shown in Figure 26, in which the first working head is in the locking process.
- Figure 40 is a cross-sectional view showing the head region of the multifunction machine shown in Figure 26, at which time the first working head is locked to the output shaft.
- Figure 41 is a cross-sectional view taken along line C-C of Figure 40.
- Figure 42 is a cross-sectional view showing the head region of the multifunction machine of the present invention, in which the second working head is locked Close to the output shaft.
- Figure 43 is a cross-sectional view taken along line D-D of Figure 42.
- Figure 44 is a cross-sectional view showing the head region of the multifunction machine of the present invention, in which the third working head is locked to the output shaft.
- Figure 45 is a cross-sectional view showing the head region of the multifunction machine of the present invention, in which case the fourth working head is locked to the output shaft.
- Figure 46 is a cross-sectional view showing the head region of the multi-function machine in the sixth embodiment of the present invention, in which the fastener and the first working head are not yet mounted on the output shaft.
- Figure 47 is a cross-sectional view showing the head region of the multifunction machine of Figure 46, in which the first working head is locked to the output shaft.
- Figure 48 is an exploded perspective view of the fastener and the positioning member in the seventh embodiment of the present invention.
- Figure 49 is a schematic illustration of the first working head being locked to the output shaft by the fasteners and positioning elements of Figure 48.
- Figure 50 is a cross-sectional view taken along line G-G of Figure 49.
- Figure 51 is a schematic cross-sectional view showing the second work mounted on the output shaft.
- Figure 52 is a perspective exploded perspective view showing the head region of the multifunction machine in the ninth embodiment of the present invention.
- Figure 53 is a perspective view showing a positioning member in a ninth embodiment of the present invention.
- Figure 54 is a front elevational view of the positioning member in the ninth embodiment of the present invention.
- Figure 55 is a plan view of a positioning member in a ninth embodiment of the present invention.
- Figure 56 is a schematic illustration of the positioning member of Figure 53 mated with a working head.
- Figure 57 is a cross-sectional view showing the head region of the multifunction machine shown in Figure 52, in which the working head is locked on the output shaft.
- Figure 58 is a perspective exploded view showing the second working head of the multi-function machine shown in Figure 52.
- Figure 59 is a schematic illustration of the positioning member of Figure 52 mated with a second working head.
- Figure 60 is a cross-sectional view of the head region of the multifunction machine of Figure 58 with the second working head locked to the output shaft.
- Figure 61 is a perspective exploded view showing the third working head of the multi-function machine shown in Figure 52.
- Figure 62 is a cross-sectional view showing the head region of the multifunction machine shown in Figure 61, at which time the third working head is locked to the output shaft.
- Figure 63 is a perspective exploded view showing the head region of the multi-function machine in the tenth embodiment of the present invention.
- Figure 64 is a perspective exploded view of the head region of the multi-function machine in the tenth embodiment of the present invention, in which the positioning member is mounted with the fastener.
- Figure 65 is a cross-sectional view showing the head region of the multifunction machine of Figure 63, in which the first working head is locked to the output shaft.
- Figure 66 is a cross-sectional view showing the head region of the multi-function machine in the eleventh embodiment of the present invention, in which the first working head is not mounted on the output shaft.
- the invention relates to a multifunction machine which can be adapted to a plurality of working heads.
- working heads There are many types of working heads in the prior art, and only a few typical working heads are listed in the specific embodiments of the present invention to illustrate the inventive concept of the present invention. Of course, unillustrated work heads are equally applicable to the present invention.
- the invention will now be further described with reference to the accompanying drawings and specific embodiments.
- the multifunction machine includes a casing 30, a motor (not shown) mounted in the casing 30, an output shaft 32 driven by a motor, and a working head 34 mounted below the output shaft 32.
- a fastener 36 is passed through the working head 34 and attached to the end of the output shaft 32 to secure the working head 34 to the output shaft 32 and is movable by the output shaft 32.
- the output shaft 32 is longitudinally disposed inside the casing 30, and its end extends from the casing 32 to a fixed distance.
- a fork member 38 is mounted on the output shaft 32.
- an eccentric device (not shown) can be transported.
- the eccentric device further drives the fork member 38 to perform a rotational swing, thereby causing the output shaft 32 to perform a rotary swing motion.
- the end of the output shaft 32 is provided with a connecting flange 33 having a large diameter.
- the connecting flange 33 is provided with a circular hole 35 through which the fastener 36 passes.
- the connecting flange 33 is integrally formed with the output shaft 32, and may be fixedly mounted on the output shaft 32. In the present invention, the connecting flange 33 is fixedly mounted on the output shaft 32 (see Fig. 4).
- the output shaft 32 can be directly provided with a threaded blind hole
- the fastener 36 is a fastening bolt, and includes an annular pressure plate 58 and a rod portion 60 extending axially from the middle of the pressure plate 58.
- the stem portion 60 includes a connecting portion 37 that is coupled to the pressure plate 58 and a threaded portion 39 connected thereto.
- the working head 34 is a straight saw blade, and it will be readily apparent to those skilled in the art that the working head 34 can also be other accessories such as a circular saw blade, a sanding disc, a scraper, and the like.
- the working head 34 is made of a metal material and includes a mounting portion 40 and a cutting portion 42 connectable to the connecting flange 33.
- the mounting portion 40 is provided with a connecting hole 44 through which the fastener 36 passes.
- the connecting hole 44 has a regular dodecagon shape.
- the connecting hole 44 may be other regular polygonal or regular polygons. Any shape such as a circle.
- the end of the cutting portion 42 is provided with a serration 46 having a cutting function.
- a drive portion 48 is provided on the connecting flange 33 at the end of the output shaft 32.
- the drive portion 48 includes a mating surface that contacts the upper surface of the mounting portion 40 of the work head 34.
- the upper and lower surfaces of the working head 34 are respectively applied between the fastener 36 and the mating surface.
- the friction generated by the mating surface and the upper surface of the working head 34 is sufficiently large that the oscillating torque on the output shaft 32 can be transmitted to the working head 34 during operation of the multifunction machine without causing The work head is slipping.
- the mating surface may be a smooth or friction surface, in this embodiment a friction surface 50.
- the friction surface 50 is formed by a plurality of regularly arranged ribs 52. These ribs 52 are generally fan-shaped and intersect at the outer edge of the circular hole 35 by self-radial inward emission. And its cross section can be trapezoidal, rectangular, semi-circular, elliptical, etc., and the tip can also be sharp. In this embodiment, the cross section is rectangular. Of course, these ribs 52 may also be radially outwardly emitted by any concentric circles concentric with the circular holes 35, or arranged in a grid. Further, the ribs 52 may be arranged in a curved shape, such as an "S" shape, and may be irregularly distributed on the output shaft.
- the quick clamping mechanism includes a locking member 54 and a drive mechanism 56 rotatable about an axis X of the output shaft 32.
- the drive mechanism 56 When the drive mechanism 56 is rotated in one direction, the locking member 54 and the fastener 36 can be driven to be threadedly locked; then, when the drive mechanism 56 is rotated in the opposite direction, the drive locking member 54 and the fastener 36 are released.
- the locking member 54 is received in the cavity of the output shaft 32.
- the locking member 54 has a substantially annular shape and is capable of freely rotating within the cavity without axial displacement, and a threaded hole is formed in the middle portion thereof to be coupled to the threaded portion 39 of the fastener 36.
- the connecting portion 37 of the fastener 36 has a substantially square cross section, and the shaft output shaft 32 is provided with a through hole 62 for receiving the connecting portion 37.
- the through hole 62 has a substantially square cross section, and the connecting portion 37 is passed through the through hole 62 so that the fastener 36 cannot be rotated relative to the output shaft 32. Therefore, the slippage of the working head is further prevented.
- the drive mechanism 56 includes a push rod 64 for engaging the lock member 54 and driving the rotation of the lock member 54, and an operating member 66 for operating the push rod 64.
- the top of the push rod 64 is mounted with a pivot 68, and the bottom portion is axially provided with a recess 70.
- the axis of the pivot 68 is perpendicular to the axis X of the output shaft 32.
- the groove 70 is sleeved on the outer circumference of the locking member 54 and drives the locking member 54 to rotate by the engaging means.
- the operating member 66 is pivotally connected to the top end of the push rod 64 via a pivot 68.
- One side of the opposite pivot 68 is provided with a cam portion 72, and the other side is a handle 74 extending substantially perpendicular to the cam portion 72. Where the handle 74 is rotated about the axis of the pivot 68, the cam portion 72 will contact the upper surface 73 of the housing to urge the push rod 64 up and down.
- the opening of the working head can also be machined to be non-closed, leaving a gap in the shank that can pass through the fastener. In this case, it is not necessary to completely remove the fastener from the locking member, and it is only necessary to loosen the locking member so as to leave a gap between the fastener and the output shaft for the mounting portion of the working head to pass through. .
- the working head 34 when the multifunction machine uses the working head, the working head 34 is first placed below the output shaft 32, and the upper surface of the mounting portion 40 of the working head 32 is attached to the output. On the rib 52 of the shaft 32.
- the rib 52 can achieve a large force transmission connection between the output shaft 32 and the working head 34 in the axial direction and the circumferential direction, so that the transmitted torque is sufficiently large to ensure the between the working head 34 and the output shaft 32. There is no relative slip.
- the output shaft 32 is rotatably oscillated by a motor (not shown). Since the output shaft 32 is provided with a friction surface 50 formed by the rib 52, the output shaft 32 and the mounting portion of the working head 34 are mounted. The upper surface of the 40 has a sufficiently large frictional force to further transmit the oscillating torque output from the output shaft 32 to the working head 34, thereby driving the working head 34 for the oscillating motion.
- the adjacent ribs 52 have a large gap therebetween, and can also receive dirt and dust on the mounting portion 40 of the working head 34, thereby ensuring the rib 52 and the working head even in a state where the working head is contaminated. There is good contact between the upper surfaces of the mounting portions 40 of 34.
- the friction surface can also be other shapes. As shown in FIGS. 5 to 6, the friction surface 50a is different from the friction surface 50 in that the rib 52a of the friction surface 50a is not a complete rib but a ring which is concentric with the axis X of the output shaft 32.
- the partition, as such, the friction surface 50a is formed by a plurality of regularly arranged projections.
- the output shaft 32 is oscillated by a motor (not shown), and the output shaft 32 is provided with friction.
- the face 50a has a sufficiently large frictional force between the output shaft 32 and the upper surface of the mounting portion 40 of the working head 34, thereby transmitting the swinging torque output from the output shaft 32 to the working head 34, thereby driving the working head 34 for the swinging motion. .
- the friction surface 50b is different from the friction surface 50 in that the friction surface 50b is formed by a plurality of regularly arranged mandrels 76.
- the plurality of mandrels 76 are generally conical, and each of the mandrels 76 is provided with an annular recess 78.
- the mandrel 76 can achieve a large force-transmitting connection between the output shaft 32 and the working head 34 both in the axial direction and in the circumferential direction, so that the transmitted torque is sufficiently large to ensure the between the working head 34 and the output shaft 32. There is no relative slip.
- the output shaft 32 is rotatably oscillated by a motor (not shown). Since the output shaft 32 is provided with the existence of the friction surface 50b formed by the core shaft 76, the output shaft 32 and the mounting portion 40 of the working head 34 are provided. The upper surface has a sufficiently large frictional force to further transmit the oscillating torque output from the output shaft 32 to the working head 34, thereby driving the working head 34 for the oscillating motion.
- the recess 78 can accommodate dirt and dust on the mounting portion 10 of the working head 34, thereby ensuring good contact between the mandrel 76 and the upper surface of the mounting portion 40 even in a state where the working head is contaminated.
- the mandrel 76 may also be provided in other geometric shapes such as square, rectangular, etc., as long as a rougher friction surface can be formed; and the mandrel 76 can be regularly or irregularly arranged on the output shaft 32.
- the friction surface 50c is different from the friction surface 50 in that the friction surface 50c includes a coating layer 80 containing a friction material, and the mounting portion of the working head 34 is mounted when the working head 34 is mounted on the output shaft 32.
- the upper surface of 40 is attached to the coating layer 80.
- the coating layer 80 can achieve a large force-transmitting connection between the output shaft 32 and the working head 34 in the axial direction and the circumferential direction, so that the transmitted torque is sufficiently large, thereby ensuring the working head 34 and the output shaft 32. There is no relative slip between them.
- the output shaft 32 is rotatably oscillated by a motor (not shown).
- the output shaft 32 is provided with a coating layer 80, there is sufficient between the output shaft 32 and the upper surface of the mounting portion 40 of the working head 34.
- the large friction force further transmits the swing torque output from the output shaft 32 to the working head 34, thereby driving the working head 34 to perform the swinging motion.
- the coating layer 80 may not be provided on the output shaft 32, and the rough friction surface may be directly ground at the end of the connecting flange 33 of the output shaft 32.
- the friction generated between the friction surface and the upper surface of the working head is large enough to transmit the oscillating torque on the output shaft to the working head without causing the working head to slip. Since the friction surface is in close fitting with the upper surface of the working head, the connecting hole of the working head can be Any other shape. Therefore, by providing an output shaft having a friction surface, it is possible to securely mount different types of working heads of the multi-function machine on the output shaft. The versatility and convenience of the multifunction machine are greatly improved.
- the multifunction machine when the working head is installed, in order to more conveniently and quickly mount the working head in position, that is, the center line of the connecting hole of the working head coincides with the axis X of the output shaft 32, the multifunction machine also The centering element 82 can be adapted.
- the second embodiment of the invention is substantially identical in construction to the first embodiment, except that the connecting flange 33 of the output shaft 32 is provided with a recess 84 which is adapted to the centering element 82.
- the recess 84 extends axially inwardly from the friction surface 50 and has an axial depth of H.
- the recess 84 has a circular inner wall 98 whose center line coincides with the axis X of the output shaft 32.
- the recess 84 has a circular cross section, and may of course be a rectangle, a regular polygon, a regular polygon or the like. Therefore, the shape of the centering element 82 adapted thereto may be a rectangle, a regular polygon, a regular polygon or the like.
- the centering element 82 is mounted between the output shaft 32 and the working head 34.
- the centering element 82 is generally cylindrical in shape and includes a first face 86 facing the recess 84, a second face 88 facing the working head 34, a peripheral wall 90 connecting the first face 86 and the second face 88, and
- the fastener 36 passes through a central locating hole 92.
- the first face 86 is opposite to the recess 84 of the output shaft 32, and a friction surface or a protrusion matching the recess 84 may be disposed thereon.
- the first face 86 may be planar without the need to provide a friction surface or projection.
- the second face 88 is opposite the working head 34 and is provided with a mating portion 94 that cooperates with the mounting portion 40 of the working head 34. When the fitting portion 94 is just engaged with the mounting portion 40 of the working head 34, the working head 34 can be easily centered.
- the first face 86 and the second face 88 are disposed in parallel, and the distance between the two is L.
- the distance L between the first face 86 and the second face 88 is not greater than the axial depth H of the recess 84.
- the first side 86 and the second side 88 may also be arranged non-parallel, but the maximum distance between the two may not be greater than the axial depth H of the recess 84.
- the centering element 82 can be adapted to a variety of working heads, so the centering element 82 typically has a diameter in the range of 22 to 30 mm, and can be 25 mm, 27 mm or the like.
- the mating portion 94 is a hollow boss 96 extending axially from the second face 88, wherein the boss 96 extends radially outwardly about the central locating aperture 92.
- the outer side wall of the boss 96 is a regular hexagon which is just engaged with the regular dodecagonal connecting hole 44 of the working head 34.
- the shape of the connecting hole of the working head may also be other shapes that are matched with the connecting holes of the working head.
- the outer side wall of the boss 96 may also be other regular polygons, Regular polygons, circles or other irregular shapes.
- the centering element 82 can be made of a plastic or metal material.
- the centering element 82 is made of plastic.
- At least two ridges 100 that are in contact with the inner wall 98 of the recess 84 are evenly disposed on the peripheral wall 90 of the centering member 82.
- ridges 100 are provided on the peripheral wall 90.
- the number of the ridges 100 may be arbitrary; moreover, the ridges 100 may be regularly distributed or irregularly distributed on the peripheral wall 90.
- the centering member 82 is provided with an expansion hole 102 which is circumferentially hooked.
- the expansion aperture 102 can provide a certain deformation of the centering element 82 when the centering element 82 is assembled within the recess 84 to facilitate mounting of the centering element 82; it is also possible to detach the centering element 82 from the recess 84. At this time, the operator borrows the tool to buckle the centering element 82.
- the number of the expansion holes 102 can be arbitrary.
- the expansion hole 102 may be a through hole penetrating the first surface 86 and the second surface 88, or may not be a through hole. Moreover, the expansion holes 102 may be uniformly distributed regularly or may be irregularly distributed on the first face 86 or the second face 88.
- the size and position of the expansion hole 102 can be set such that the position of the expansion hole 102 and the position of the ridge 100 correspond one-to-one in the circumferential direction.
- the length of the expansion hole 102 in the extending direction is longer than the length of the ridge 100 in the extending direction.
- the circle surrounded by the center line of the expansion hole 102 is concentric with the center positioning hole 92, and the radius of the circle in which the expansion hole 102 is located is twice the radius of the center positioning hole 92.
- the centering member 82 is first mounted in the recess 84, and the working head 34 is sleeved on the centering member 82.
- the mounting portion 40 of the working head 34 is mated with the mating portion 94 of the centering member 82 such that the centerline of the connecting hole 44 of the working head coincides with the axis X of the output shaft 32; then, the fastener 36 is worn
- the through hole 44 and the center positioning hole 92 are further engaged with the threaded holes of the locking member.
- the handle 74 is operated to rotate about the axis of the pivot 68, thereby driving the push rod 64 to move downward, and the groove 70 of the push rod 64 Engaged with the locking member 54, at this time, the handle 74 can be operated to rotate along the axis X of the output shaft 32 in the tightening direction, thereby driving the locking member 54 to rotate, and the locking member 54 and the fastener 36 are threaded.
- the lock is secured to secure the working head 34 to the output shaft 32.
- the centering element 82 is fitted within the recess 84, and the centering element 82 can be tightly engaged with the recess 84 so that it is difficult to rotate relative to the recess 84; of course, the centering element 82 can also be larger with the recess 84.
- the gap allows it to be easily rotated relative to the recess 84. This is because, friction The friction generated between the face 50 and the upper surface of the mounting portion 40 of the working head 34 is sufficiently large, and the friction surface 50 ensures the mounting portion 40 of the working head 34 relative to the output shaft both in the axial direction and in the circumferential direction.
- the centering element 82 can be rotated relative to the recess 84 even when installed, but after being threadedly locked by the locking member 54 and the fastener 36, the centering member 82 will be associated with the working head 34 along with the output shaft 32. Swing motion.
- the working head is fixedly mounted on the output shaft by matching the projection on the output shaft with the star opening of the working head.
- the projections and the openings together function as a centering function, a fixing function and a torque function, so that the projections and the openings are worn very quickly.
- the centering member 82 is used for centering, thereby facilitating the separation of the centering function from the fixed function and/or the torque function. Therefore, the wear of the centering member 82, the friction surface 50, the connecting hole 44 of the working head 34, and the like can be reduced.
- the centering element 82 can use a relatively low cost material to design a corresponding centering element according to the working head having various mounting portions. Therefore, the multifunction machine can be matched with various types of working heads. In the case of no increase in cost.
- the centering member 82 is rotatable relative to the recess 84, the angular position of the working head 34 relative to the output shaft 32 can be conveniently adjusted as needed.
- the friction surface 50 is formed by a plurality of ribs 52.
- the other friction surfaces of the first embodiment are also applicable.
- centering member of the present invention is not limited to the description in the second embodiment, and other shapes of centering members will be specifically described below.
- the working head 34b has substantially the same structure as the working head 34 in the second embodiment, and has the mounting portion 40b and the cutting portion 42b, respectively.
- a connecting hole 44b is formed in the mounting portion 40b. The difference is that the shape of the connecting hole 44b is different from the shape of the connecting hole 44 of the working head 34.
- the connecting hole 44b includes eight radially extending circular ridges 104b through which the curved segments 106b passing between adjacent circular ridges 104b are continuously connected.
- the centering element 82b is also different from the centering element 82 in the second embodiment with respect to the change of the connecting hole 44b.
- the first face 86b, the ridge 100b and the expansion hole 102b of the centering member 82b are identical in construction to the first face 86, the ridge 100 and the expansion hole 102 in the second embodiment.
- the difference is that the fitting portion 94b provided in the second surface 88b to cooperate with the mounting portion 40b of the working head 34b is different from the fitting portion 94.
- the forming portion 94b includes an axially extending portion from the second surface 88b and is circumferentially uniform.
- Four projections 108b are provided, each projection 108b being a circular tip extending radially outward from the outer edge of the central locating aperture 92b.
- the projection 108b coincides with the circular ridge 104b and the curved section 106b on the connecting hole 44b of the working head 34b, so that the center line of the connecting hole 44b of the working head 34b coincides with the axis X of the output shaft 32, thereby centering effect.
- the circular ridges 104b of the working heads 34b are not limited to eight, as long as they are larger than two or more, and adjacent circular ridges are continuously connected to each other by curved segments.
- the projections 108b of the fitting portion 94b are also limited to four, as long as they are more than two.
- the circular ridge 104b is an integral multiple of the projection 108b.
- the protrusion 108b may not be provided as a rounded tip, but may be other shapes such as a rectangle, a trapezoid or the like, and only the shape of the protrusion 108b may be matched with the circular ridge 104b or the curved section 106b.
- the projections 108b can also be arranged uniformly as needed.
- the centering element 82b is first installed in the recess 84, and the working head 34b is sleeved on the centering element 82b, and the working head 34b is
- the mounting portion 40b is mated with the fitting portion 94b of the centering member 82b such that the center line of the connecting hole 44b of the working head coincides with the axis X of the output shaft 32; then, referring to the above method, the working head is moved by the quick clamping mechanism 34 is fixed to the output shaft 32.
- the output shaft 32 is oscillated by a motor (not shown). Since the output shaft 32 is provided with the friction surface 50 formed by the rib 52, the output shaft 32 and the mounting portion 40b of the working head 34b are provided. The upper surface has a sufficiently large frictional force to further transmit the oscillating torque output from the output shaft 32 to the working head 34b, thereby driving the working head 34b to perform a oscillating motion.
- the friction surface 50 is formed by a plurality of ribs 52.
- the other friction surfaces of the first embodiment are also applicable.
- the working head 34c has substantially the same structure as the working head 34 in the second embodiment, and has the mounting portion 40c and the cutting portion 42c, respectively.
- a connection hole 44c is formed in the mounting portion 40c. The difference is that the shape of the connecting hole 44c is different from the shape of the connecting hole 44 of the working head 34.
- the connecting hole 44c includes twelve holes 110c spaced apart on one circumference and through holes l l l c through which the fastener 36 passes.
- the centering element 82c is also different from the centering element 82 in the second embodiment with respect to the change of the connecting hole 44c.
- the first face 86c, the ridge 100c and the expansion hole 102c of the centering member 82bc are identical in structure to the first face 86, the ridge 100 and the expansion hole 102b in the second embodiment.
- the difference is that the fitting portion 94c provided in the second surface 88c to be engaged with the mounting portion 40c is different from the fitting portion 94.
- the shape portion 94c includes an axially extending portion from the second surface 88c and is circumferentially uniform. Twelve locking elements 112c are provided, each of which is disposed outside of the central positioning hole 92c. And the twelve locking members 112c are just matched with the twelve holes 110c of the working head 34b, so that the center line of the connecting hole 44c of the working head 34c coincides with the axis X of the output shaft 32, thereby centering.
- the connecting hole 44c on the working head 34c is not limited to the twelve holes 110c as long as it is more than two.
- the locking member 112c of the fitting portion 94c is also limited to twelve, as long as it is more than two, but preferably has a multiple relationship with the hole 110c.
- the number of holes 110c is an integer multiple of the number of locking elements 112c.
- the locking member 112c can also be arranged without uniform as needed.
- the cross section of the hole 110c is trapezoidal, and accordingly, the cross section of the locking member 112c of the engaging portion 94c is also trapezoidal.
- the locking member 112c has at least one chamfer for supporting the push-in process, and the working head 34c functions as a centering by the interaction of the locking member 112c and the hole 110c.
- cross-sectional shape of the locking member 112c and the hole 110c is not limited to a trapezoid, but may be one of a rectangle, a triangle, an arc, a square, a circle, or an ellipse.
- the centering element 82c is first mounted in the recess 84, and the working head 34c is sleeved on the centering element 82c, and the working head 34c is
- the mounting portion 40c is mated with the fitting portion 94c of the centering member 82c such that the center line of the connecting hole 44c of the working head 34c coincides with the axis X of the output shaft 32; then, referring to the above method, the working will be performed by the quick clamping mechanism
- the head 34c is fixed to the output shaft 32.
- the output shaft 32 is rotatably oscillated by a motor (not shown). Since the output shaft 32 is provided with the friction surface 50 formed by the rib 52, the output shaft 32 and the mounting portion 40c of the working head 34c are provided. The upper surface has a sufficiently large frictional force to further transmit the oscillating torque output from the output shaft 32 to the working head 34c, thereby driving the working head 34c to perform a oscillating motion.
- the friction surface 50 is formed by a plurality of ribs 52.
- the other friction surfaces of the first embodiment are also applicable.
- the attachment hole 44c includes twelve holes 110c spaced apart on one circumference and a through hole 111c through which the fastener 36 passes.
- the centering element 82 can also be adapted.
- the outer sidewall of the hollow boss 96 of the centering element 82 can be circular.
- the through hole 111c is just matched with the boss 96, so that the center line of the connecting hole 44c of the working head 34c coincides with the axis X of the output shaft 32, thereby facilitating the installation of the working head.
- the multi-function machine can also be fitted with positioning elements and elastic elements.
- the resilient element is used to urge the positioning element to move axially or radially in a direction that is in contact with the working head.
- the fifth embodiment of the present invention is basically the same as the second embodiment, and the same portions are not described again, and the differences will be described in detail below.
- a heat insulating sleeve 250 is attached to the pressure plate 242 of the fastener 236.
- the insulating sleeve 250 is wrapped around the pressure plate 242 to prevent damage to the operator due to heat transfer from the output shaft 232 to the pressure plate 242 when the working head needs to be replaced after a period of use.
- the insulating sleeve 250 is uniformly provided with a hook 252 in the circumferential direction, and the clamping plate 242 is provided with a card slot 254.
- the heat insulating sleeve 250 is wrapped around the pressure plate 242 by the hook 252 being snapped into the card slot 254.
- the multifunction machine includes a positioning element 256 that mates with the working head.
- the positioning member 256 can be adapted to a working head having a connecting hole having a different minimum inner diameter, so that the working head can be easily and quickly mounted in position when different types of working heads are installed. That is, the center line of the connecting hole of the different types of working heads can substantially coincide with the axis X of the output shaft 232.
- the center line of the connecting hole of the working head and the axis X of the output shaft may not coincide, and the distance between the two may also satisfy the convenient, convenient and quick working head. The installation is in place.
- the multifunction machine also includes an elastic member that causes the positioning member 256 to always move axially in a direction in contact with the first working head 234a.
- the positioning member 256 is sleeved on the fastener 236, and the elastic member is disposed between the pressure plate 242 and the positioning member 256.
- the elastic member is a conical spring 257, and the cone spring 257 takes up a small space when compressed. It can be understood that the elastic member can also be a compression spring or the like.
- a stop ring 259 with the stop positioning member 256 disengaged is provided on the fastener 236.
- the positioning element 256 is sleeved on the fastener 236, and an elastic element is disposed therebetween to form a separate fastening device, which can be used to assemble a plurality of working heads into one multifunctional function. on board.
- a stop ring 259 with the stop positioning member 256 disengaged is provided on the fastener 236.
- the fastening unit facilitates the installation of the working head.
- the fastening device can also be sold as a separate accessory.
- the positioning element 256 can also be disposed within the output shaft 232, and the resilient element is disposed between the output shaft 232 and the positioning element 256.
- 27 to 30 show a fifth embodiment of the present invention, and several different classes are listed. Type of work head.
- the first working head 234a is a straight saw blade that includes a first mounting portion 258a and a first cutting portion 260a, wherein the first mounting portion 258a is for attachment to the output shaft 232.
- the first mounting portion 258a is provided with a first connecting hole 262a through which the fastener 236 passes.
- the first connecting hole 262a has a regular dodecagon shape with a minimum inscribed circle having a diameter dl.
- the end of the first cutting portion 260a is provided with a serration 264a having a cutting function.
- the second working head 234b is a straight saw blade that includes a second mounting portion 258b and a second cutting portion 260b, wherein the second mounting portion 258b is for attachment to the output shaft 232.
- the second mounting portion 258b is provided with a second connecting hole 262b through which the fastener 236 passes.
- the second connecting hole 262b is circular and has a diameter d2.
- the end of the second cutting portion 260b is provided with a serration 264b having a cutting function.
- the third working head 234c is a straight saw blade including a third mounting portion 258c and a third cutting portion 260c, wherein the third mounting portion 258c is for connection to the output shaft 232.
- the third mounting portion 258c is provided with a third connecting hole 262c through which the fastener 236 passes, and the third connecting hole 262c is a star-shaped opening having eight rounded corners, and the rounded corners are continuously connected.
- the diameter of the smallest inscribed circle is equal to the diameter of the second connecting hole and is d2.
- the end of the third cutting portion 260c is provided with a serration 264c having a cutting function.
- the fourth working head 234d is a straight saw blade including a fourth mounting portion 258d and a fourth cutting portion 260d connectable to the output shaft 232.
- the fourth mounting portion 258d defines a fourth connecting hole 262d through which the fastener 236 passes.
- the fourth connecting hole 262d is circular and has a diameter d3.
- the end of the fourth cutting portion 260d is provided with a serration 264d having a cutting function.
- the fourth attachment hole 262d is a non-closed circular hole provided with a notch.
- the positioning member 256 has a central aperture 265 through which the fastener 236 passes and a peripheral wall 266 disposed around the central aperture 265.
- the peripheral wall 266 includes an outer peripheral surface 268 that cooperates with the attachment hole of the working head for positioning of the working head.
- the outer peripheral surface 268 includes at least a first outer contour having a first largest radial dimension and a second outer contour having a second largest radial dimension, wherein the first largest radial dimension is unequal to the second radial dimension. Therefore, the first outer contour and the second outer contour are adapted to be at least partially in contact with the working heads having the connecting holes of different minimum inner diameters for different types of working head positioning.
- the first outer contour or the second outer contour may be in face-to-face contact when in contact with the smallest inner diameter of the corresponding connecting aperture. If the surface is in contact with the surface, the contact surface is relatively large and the positioning is relatively reliable.
- the minimum outer diameter of the first outer contour or the second outer contour and the corresponding connecting hole may also be point contact. Which is connected With at least three contacts, the positioning of the corresponding working head can be achieved.
- the at least three contact points form at least one right triangle or acute triangle.
- the change in the maximum radial dimension of the outer peripheral surface 268 from the first outer contour to the second outer contour may be linear or non-linear.
- the outer peripheral surface 268 includes at least two cylindrical faces of different maximum radial dimensions, at least two of which are for at least partial contact with the working head having connecting holes of different minimum inner diameters.
- the outer peripheral surface 268 includes a first cylindrical surface 270 and a second cylindrical surface 272.
- a plurality of identical first outer contours 274 having a first maximum radial dimension D 1 form a first cylindrical surface 270; and a plurality of identical second outer contours 278 having a second largest radial dimension D2 form a second cylindrical surface 272.
- first outer contour 274 and the second outer contour 278 have the same shape and are all circular. It can be understood that the positioning of the corresponding working head can also be achieved if the shapes of the first outer contour and the second outer contour are different.
- the shapes of the first outer contour 274 and the second outer contour 278 are both circular. It will be readily understood by those skilled in the art that the shapes of the first outer contour 274 and the second outer contour 278 are not limited to circular shapes, and may be other shapes such as polygonal or elliptical shapes.
- first cylindrical surface 270 and the second cylindrical surface 272 are axially interrupted.
- the outer peripheral surface 268 further includes a connecting surface for connecting the first cylindrical surface 270 and the second cylindrical surface 272, and the connecting surface may be a conical surface having a linear change or a concave or convex surface, or the like; A curved surface is formed.
- the joining faces are conical faces 280 which are formed by outer profiles having different maximum radial dimensions in the axial direction. Therefore, different outer contours can be fitted to the working heads having connecting holes of different minimum inner diameters.
- at least one conical surface is provided on the outer peripheral surface 268, and it is equally possible to position different types of working heads.
- first cylindrical surface 270 and the second cylindrical surface 272 may also be axially continuous.
- the first cylindrical surface 270 and the second cylindrical surface 272 are joined by a stepped surface perpendicular to the first cylindrical surface 270 and the second cylindrical surface 272.
- a cylindrical surface is preferably fitted with a working head of a minimum inner diameter. Therefore, if the outer peripheral surface 268 of the positioning member 256 is formed only by the cylindrical surface, the corresponding cylindrical surface can be set according to the different inner diameters of the different working heads.
- chamfering is performed between the first cylindrical surface 270 and the conical surface 280 and between the second cylindrical surface 272 and the conical surface 280. This facilitates processing and facilitates the installation of the working head.
- the outer peripheral surface 268 is longitudinally intersected with the center line 273 passing through the center hole 265.
- Crossing forms a line of intersection.
- the intersection of the outer peripheral surface 268 and the longitudinal section passing through the center line 273 is composed of three straight line segments.
- the intersection of the first and second cylindrical faces 270 and 272 with the longitudinal section is at an angle of 0 degrees with the centerline 273, and the intersection of the conical surface 280 and the longitudinal section is at an angle a to the centerline 273.
- the angle a is approximately 50 degrees.
- the angle a can be set to an arbitrary angle as needed.
- the intersection line can also be a non-linear line, such as one of a curve or an arc, or a combination of lines, curves and arcs.
- the minimum inner diameter dl of the first connecting hole 262a is equivalent to the first maximum diameter D 1 of the first outer contour 274.
- the first working head 234a is sleeved on the first cylindrical surface 270 such that the first connecting hole 262a is just seated on the first cylindrical surface 270 to realize the positioning of the first working head 234a.
- the minimum inner diameter dl of the first connecting hole 262a may be equivalent to the first maximum diameter D1.
- the minimum inner diameter d1 of the first connecting hole 262a is equal to or slightly larger than the first maximum diameter D1 of the first outer contour 274. Therefore, the positioning of the first working head 234a can be realized only by the first cylindrical surface 270 being at least partially in contact with the first connecting hole 262a.
- the height of the first cylindrical surface 270 is equivalent to the thickness of the first connecting hole 262a.
- the height of the first cylindrical surface 270 may be equivalent to the thickness of the first connecting hole 262a, and the thickness of the first connecting hole 262 may be slightly smaller than or equal to the height of the first cylindrical surface 270.
- the positioning element 256 is also provided with a bottom surface 276 that is coupled to the first cylindrical surface 270, the bottom surface 276 having a diameter greater than the first maximum diameter D1. When the first working head 234a is sleeved on the positioning member 256, the bottom surface 276 prevents the first working head 234a from being disengaged from the positioning member 256.
- the diameter d2 of the second connecting hole 262b is equivalent to the second maximum diameter D2 of the second outer contour 278.
- the second working head 234b is sleeved on the second cylindrical surface 272 such that the second connecting hole 262b is just seated on the second cylindrical surface 272 to realize the positioning of the second working head 234b.
- the diameter d2 of the second connecting hole 262b may be equivalent to the second maximum diameter D2.
- the minimum inner diameter d1 of the second connecting hole 262b is equal to or slightly larger than the first maximum diameter D1 of the first outer contour 274.
- the second connecting hole 262b of the second working head 234b cooperates with the second cylindrical surface 272 to be in surface contact of the entire circumference. , the contact surface is larger and the positioning is more reliable.
- the height of the second cylindrical surface 272 is equivalent to the thickness of the second connecting hole 262b.
- the height of the second cylindrical surface 272 is equivalent to the thickness of the second connection hole 262b, and may be a connection hole.
- the thickness of 262 is slightly less than or equal to the height of the second cylindrical surface 272.
- the minimum inner diameter d2 of the third connecting hole 262c is equivalent to the second largest diameter D2 of the second outer contour 278.
- the third working head 234c is sleeved on the second cylindrical surface 272 such that the third connecting hole 262c is just seated on the second cylindrical surface 272 to realize the positioning of the third working head 234c.
- the minimum inner diameter d2 of the third connection hole 262c may be equivalent to the second maximum diameter D2.
- the minimum inner diameter d2 of the third connection hole 262c is equal to or slightly larger than the second maximum diameter D2 of the second outer contour 78.
- the height of the second cylindrical surface 272 may be equivalent to the thickness of the third connecting hole 262c, such that the thickness of the connecting hole 262 is slightly smaller than or equal to the height of the second cylindrical surface 272.
- the conical surface 280 includes a third outer contour 28 1 having a third largest diameter D 3 .
- the diameter d3 of the fourth connecting hole 262d is equal to the third largest diameter D3 of the third outer contour 28 1 .
- the fourth working head 234d is sleeved on the conical surface 280 such that the fourth connecting hole 262d is in contact with the third outer contour 28 1 to realize the fourth working head 234d. Positioning.
- the diameter d3 of the fourth connecting hole 262d is exactly equal to the third maximum diameter D3, and the cooperation of the fourth connecting hole 262d and the third outer contour 28 1 is the whole The line contact of the circumference makes the positioning more reliable.
- the mating surface 282 is a friction surface formed by a plurality of ribs 286.
- the other friction surfaces of the first embodiment are equally applicable.
- the multifunction machine includes a quick clamping mechanism which is substantially the same as that of the first embodiment.
- the first working head 234a is first sleeved on the positioning component 256, so that the first connecting hole 262a cooperates with the first cylindrical surface 270 for positioning, and the positioning component 256 is The cone spring 257 abuts against the stop ring 259; the fastener 236 to which the first working head 234a is mounted is then attached to the output shaft 232; at this time, the handle 295 is operated to surround the axis of the pivot 292.
- the cam portion 294 is in contact with the contact surface 296 of the housing, thereby driving the push rod 290 to move downwardly, so that the recess 293 of the push rod 290 is engaged with the locking member 287; at this time, the operating handle 295 surrounds the axis of the output shaft 232.
- the X rotates in the tightening direction, thereby causing the locking member 287 to rotate, and the locking member 287 and the fastener 236 are screwed, thereby fixing the first working head 234a to the output shaft 232.
- the fastener 236 is axially moved in the E direction by the engagement of the locking member 287.
- the upper surface 283a of the first mounting portion 258a of the first working head 234a is moved.
- a lower surface 297a of a mounting portion 258a overlies the upper surface 298 of the platen 242.
- the handle 295 is operated to rotate back about the axis of the pivot 292 to an initial position that is substantially perpendicular to the output shaft 232.
- the rib 286 can realize a large force transmission connection between the output shaft 232 and the first working head 234a in the axial direction and the circumferential direction, the transmitted torque is sufficiently large, thereby ensuring the first working head 234a. There is no relative slip between the output shaft 232 and the output shaft 232.
- the output shaft 232 is oscillated by a motor (not shown), and the swing torque output from the output shaft 232 is further transmitted to the first working head 234a, thereby driving the first working head 234a to perform a swinging motion.
- the first working head 234a When the first working head 234a needs to be disassembled, only the handle 295 is operated, and the push rod 290 is moved downward to make the groove 293 of the push rod 290 engage with the locking member 287. At this time, the operating handle 295 surrounds the axis of the output shaft 232. The X rotates in the unscrewing direction, thereby causing the locking member 287 to rotate until the locking member 287 is completely disengaged from the fastener 236, and the fastener 236 can be detached from the output shaft 232. , the first working head 234a is taken out. Since the attachment hole 44 in the first mounting portion 258a of the first working head 234a is closed, the locking member 287 and the fastener 236 need to be completely disengaged to be removed from the output shaft 232.
- the first mounting portion 258a of the first working head 234a defines a first central surface 261a parallel to the mating surface 282, the first central surface 261a to the upper surface of the first mounting portion 258a.
- the distance between 283 a and the lower surface 297 a is equal.
- Figure 41 is a cross-sectional view taken along line C-C of Figure 40.
- the positioning member 256 has a first cross section 263a in the first central plane 261a.
- the first cross section 263a is annular, and the first outer contour 274 forms a first circumcircle which is in contact with the first connecting hole 262a of the first working head 234a.
- the diameter of the first circumscribed circle is the radial dimension D l of the first outer contour 274.
- the diameter of the smallest inscribed circle of the first connecting hole 262a is d l which is equivalent to the diameter D 1 of the first circumscribed circle, thereby realizing the positioning of the first working head 234a.
- the second working head 234b when the second working head 234b is used, the second working head 234b is first sleeved on the positioning member 256, so that the second connecting hole 262b is used with the second cylindrical surface 272. Positioning, at this time, the positioning member 256 abuts against the stop ring 259 under the action of the conical spring 257; then the fastener 236 on which the second working head 234b is mounted is attached to the output shaft 232; Rotating about the axis of the pivot 292, thereby driving the push rod 290 to move downward, so that the groove 293 of the push rod 290 is engaged with the locking member 287; then the operating handle 295 surrounds the output shaft 232 The axis X rotates in the tightening direction, thereby causing the locking member 287 to rotate, thereby locking the locking member 287 and the fastener 236, thereby fixing the second working head 234b to the output shaft 232.
- the fastener 236 is axially moved in the E direction by the cooperation of the locking member 287.
- the upper surface 283b of the second working head 234b is attached to the friction surface.
- the handle 295 is operated to rotate back about the axis of the pivot 292 to an initial position that is substantially perpendicular to the output shaft 232.
- the second mounting portion 258b of the second working head 234b defines a second center surface 261b parallel to the mating surface 282, and the second center surface 26 1b to the upper surface 283b of the second mounting portion 258b.
- the distance from the lower surface 297b is equal.
- Figure 43 is a cross-sectional view taken along line D-D of Figure 42.
- the positioning member 256 has a second cross section 263b in the second center plane 261b.
- the second cross section 263b is annular, and the second outer contour 78 forms a second circumcircle which is in contact with the second connecting hole 262b of the second working head 234b.
- the diameter of the second circumscribed circle is the second outer contour 78 radial dimension D2.
- the diameter of the smallest inscribed circle of the second connecting hole 262b is d2 which is equivalent to the diameter D2 of the second circumscribed circle, thereby realizing the positioning of the second working head 234b.
- the first cross section has the same shape as the second cross section, both of which are circular, but the diameters of the circumscribed circles are different.
- the shapes of the first cross section and the second cross section may also be different.
- the first cross section is circular, and the second cross section is polygonal; or the first cross section is a polygon, the second cross section is an ellipse, and the like. That is, the circumscribed circle of the largest outer contour of the positioning member 256 is equivalent to the minimum inscribed circle size of the connecting hole of the working head, so that the corresponding working head can be positioned.
- the shape of the cross section of the positioning member 256 regardless of the shape of the connecting holes themselves.
- the third working head 234c when used, the third working head 234c is first sleeved on the positioning member 256, so that the third connecting hole 262c cooperates with the second cylindrical surface 272 for positioning.
- the positioning member 256 abuts against the stop ring 259 under the action of the conical spring 257; then the fastener 236 to which the third working head 234c is mounted is attached to the output shaft 232; at this time, the handle 295 is operated to It rotates about the axis of the pivot 292, which in turn drives the push rod 290 to move downwardly, so that the groove 293 of the push rod 290 engages with the locking member 287; then the operating handle 295 is rotated along the axis X of the output shaft 232. Rotating, thereby driving the locking member 287 to rotate, so that the locking member 287 and The fastener 236 is threaded to secure the third working head 234c to the output shaft 232.
- the fastener 236 is axially moved along the E direction under the cooperation of the locking member 287.
- the upper surface 283c of the third working head 234c is attached to the mating surface 282.
- continuing to operate the handle 295 to rotate about the axis X of the output shaft 232 causes the positioning member 256 to move axially in the F direction while compressing the conical spring 257 until the lower surface 297c of the third working head 234c is attached to the pressing plate 242.
- the third working head 234c is fixed to the output shaft 232.
- the fourth working head 234d when the fourth working head 234d is used, the fourth working head 234d is first sleeved on the positioning member 256, so that the fourth connecting hole 62d cooperates with the conical surface 280 for positioning.
- the positioning member 256 abuts against the stop ring 259 under the action of the conical spring 257; then the fastener 236 on which the fourth working head 234d is mounted is attached to the output shaft 232; at this time, the handle 295 is operated to surround it.
- the axis of the pivot 292 rotates, thereby driving the push rod 290 to move downward, so that the groove 293 of the push rod 290 engages with the locking member 287; then the operating handle 295 rotates along the axis X of the output shaft 232 in the tightening direction. Thereby, the locking member 287 is rotated to screw the locking member 287 and the fastener 236 to fix the fourth working head 234d on the output shaft 232.
- the fastener 236 is axially moved along the E direction under the cooperation of the locking member 287.
- the upper surface 283d of the fourth working head 234d is attached to the mating surface 282.
- continuing to operate the handle 295 to rotate about the axis X of the output shaft 232 causes the positioning member 256 to move axially in the F direction while compressing the conical spring 257 until the lower surface 297d of the fourth working head 234d is attached to the pressing plate 242.
- the fourth working head 234d is fixed to the output shaft 232.
- the positioning element 256 is provided with at least two different maximum radial dimension outer contours at least partially in contact with the inner diameters of different types of working heads, so that different types of working heads can be positioned. Moreover, regardless of the shape of the connecting holes themselves, since the outer contour is in contact with the inner diameter of the working head, the connecting holes of the working head can be of any other shape. Therefore, by arranging the positioning elements 256 having outer contours having different maximum radial dimensions, different types of working heads connected by the multi-function machine can be quickly and accurately mounted to the corresponding positions.
- the working head is fixedly mounted on the output shaft by matching the protrusion on the output shaft with the star connection hole of the working head.
- the protrusion and the connecting hole together function as a positioning function and are fixed
- the function and torque function causes the bumps and connecting holes to wear very quickly.
- the positioning member 256 is used for positioning, and the friction surface and the surface of the working head are used for fixing function and/or torque function by the locking mechanism. In this way, the positioning function is advantageously separated from the fixed function and/or the torque function. Therefore, the wear of the positioning member 256, the friction surface, the connection hole of the working head, and the like can be reduced.
- the outer contour of the positioning member 256 is in contact with the smallest inner diameter of the connecting hole, it is used only for positioning, and the relative positions of the working head and the positioning member are not limited. Therefore, the operator can easily adjust the angular position of the working head relative to the output shaft 232 as needed.
- the sixth embodiment of the present invention is basically the same as the fifth embodiment except that the output shaft 232 is directly provided with a threaded blind hole 314, and the fastener 316 is threaded tight. Solid bolts.
- the first working head 234a When the first working head 234a is installed, the first working head 234a is first sleeved on the positioning member 256, so that the first connecting hole 262a cooperates with the first cylindrical surface 270 for positioning, and the positioning member 256 acts at the cone spring 257.
- the fastener 3 16 mounted with the first working head 234a is attached to the output shaft 232; at this time, only the fastener 3 16 is connected to the threaded blind hole 314, and then The first working head 234a can be easily attached to the output shaft 232 by rotating the fastener 316 in the tightening direction.
- the seventh embodiment of the present invention is substantially the same as the sixth embodiment, except that: the positioning member 256 in the sixth embodiment performs axial movement to adapt to different working heads; The positioning element 420 in the seventh embodiment adapts to different working heads by radial movement.
- the elastic member 422 is disposed in the fastener 424, and the elastic member 422 urges the positioning member 420 to always move radially toward the contact hole of the working head.
- the elastic member is a spring 422.
- the spring can also be a compression spring or a tension spring.
- the locating element 420 includes at least two locating blocks 426 circumferentially disposed on the fastener 424 that are generally radially displaced by the spring 422 in a direction in contact with the connecting holes of the working head.
- a stop (not shown) is also provided between the fastener 424 and the positioning block 426 to prevent the positioning block 426 from disengaging the fastener 424.
- the positioning blocks 426 are four and are evenly disposed on the circumference of the fastener 424. Of course, these positioning blocks 426 can also be disposed at any angle in the circumferential direction of the fastener 424.
- the first working head 234a when the first working head 234a is installed, the first working head 234a is first sleeved on the positioning component 420, so that the first connecting hole 262a cooperates with the positioning block 426 for positioning; then the first working head will be installed.
- the fastener 424 of the 234a is attached to the output shaft 232; at this time, only the fastener 424 is connected to the thread blind hole 314, and then the fastener 424 is rotated in the tightening direction, which can be easily
- the first working head 234a is fixed to the output shaft 232.
- the first mounting portion 258a of the first working head 234a defines a first central surface 261a parallel to the mating surface 282, the first central surface 261a to the upper surface 283a and the lower surface 297a of the first mounting portion 258a The distance is equal.
- Figure 50 is a cross-sectional view taken along line G-G of Figure 49.
- the positioning element 420 has a first cross-section 428 within the first central surface 261a.
- the shape of the first cross section 428 is substantially four separate rectangles, which constitute the first circumscribed circle having a diameter D l .
- the diameter of the smallest inscribed circle of the first connecting hole 262a is dl, thereby realizing the positioning of the first working head 234a.
- the diameter D 1 of the first circumscribed circle is equivalent to the diameter dl of the minimum inscribed circle of the first connecting hole 262a, and the diameter D l of the first circumscribed circle is equal to or slightly larger than the first connection.
- the diameter dl of the smallest inscribed circle of the hole 262a is equivalent to the diameter dl of the minimum inscribed circle of the first connecting hole 262a.
- Figure 51 is a cross-sectional view along the second center face 261b of the second work head 234b.
- the positioning member 420 has a second cross section 430 in the second center plane 261b.
- the second cross section 430 has the same shape as the first cross section 428, which is substantially four separate rectangles, but which constitutes the first circumscribed circle having a diameter D2.
- D2 the diameter of the smallest inscribed circle of the second connecting hole 262b which is d l , thereby realizing the positioning of the second working head 234b.
- the diameter D 1 of the first circumscribed circle is equivalent to the diameter dl of the minimum inscribed circle of the first connecting hole 262a such that the diameter D 1 of the first circumscribed circle is substantially equal to the diameter dl of the minimum inscribed circle of the first connecting hole 262a.
- the positioning block 426 is set to a circular dust end or a circular end at the end that is mated with the working head.
- the positioning member 420, the fastener 424, and the elastic member 422 in this embodiment may also constitute a separate fastening device that can be used to assemble a plurality of working heads to a multi-function machine.
- this fastening device facilitates the installation of the working head.
- the fastening device can also be sold as a separate accessory.
- the eighth embodiment of the present invention is substantially the same as the fifth, sixth, and seventh embodiments, except that the positioning elements in the first three embodiments are moved axially or radially to fit different working heads; However, the positioning elements in the eighth embodiment are adapted to different working heads by their own deformation.
- the positioning element is a deforming member that can be disposed on the fastener or on the transport shaft. The deforming member is in contact with the first connecting hole and forms a tangent to the first connecting hole in the first central plane a first circumscribed circle; the deforming member is in contact with the second connecting hole and forms a second circumscribed circle tangential to the second connecting hole in the second central plane. Wherein the minimum inner diameter of the first connecting hole and the second connecting hole are different, and the diameters of the first circumscribed circle and the second circumscribed circle are also different.
- the positioning element in this embodiment can also be constructed as a separate fastening device with the fastener, which can be used to assemble a plurality of working heads onto a multi-function machine.
- the fastening device facilitates the assembly of the multi-function machine.
- the fastening device can also be sold as a separate accessory.
- the positioning elements are also provided with a torque-transmitting part.
- 52 to 62 show a ninth embodiment of the present invention.
- the ninth embodiment of the present invention is basically identical in structure to the second embodiment except for the specific structure and function of the positioning member.
- the end of the output shaft 532 is provided with a connecting flange 558.
- the connecting flange 558 is provided with a mating surface 560 that is in contact with the upper surface of the working head 534.
- the upper and lower surfaces of the working head 534 are respectively applied between the pressing plate 542 and the mating surface 560.
- the frictional force generated by the mating surface 560 and the upper surface of the working head 534 is sufficiently large that the swinging torque on the output shaft 532 can be transmitted to the working head 534 during operation of the multifunction machine, and The work head 534 is caused to slip.
- the mating surface 560 is a friction surface formed by a plurality of regularly arranged ribs.
- the other friction surfaces of the first embodiment are also applicable.
- the multifunction machine can be connected to different types of working heads, and these working heads can be mounted on the output shaft 532 at any angle. However, it also causes some troubles, such as the inability to quickly and accurately adjust the angle of the various working heads relative to the output shaft 532 during installation.
- the positioning member 562 has a central bore 564 through which the fastener 536 passes and an adapter disk 566.
- the central aperture 564 is generally square in cross-section and mates with the connector 546.
- the adapter disk 566 is provided with opposite first and second ends, wherein the first end faces the output shaft 532 and has a disk-shaped body 568, the second end facing the working head 534.
- the positioning element 562 includes a form 570, an adapter that mates with the working head 534.
- the adapter portion includes at least a first adapter portion 572 and a second adapter portion 574.
- the first adapter portion 572 and the second adapter portion 574 have different projection shapes on a plane perpendicular to the output shaft 532, thereby A working head for connecting at least two connection holes having different shapes.
- the thickness of both of the adapter portions is more than 1.2 mm, preferably 1.2 mm, so that the corresponding working head can be mounted more stably.
- the fitting portion 570 is formed by radially outwardly extending from the outer circumference of the disc-shaped body 568, and the first adapter portion 572 and the second adapter portion 574 are axially protruded from one side of the disc-shaped body 568.
- the mating portion 570 includes at least one form-fitting member 576 that extends radially outward from the outer circumference of the disc-shaped body 568.
- the mating portion 570 includes four circumferentially uniformly disposed mating members 576, and each of the mating members 576 includes two sidewalls 573 that are relatively parallel with respect to the center of the disc-shaped body 568 and the connecting sides. End wall 575 of wall 573.
- the end wall 575 is perpendicular to the two side walls 573.
- the two side walls 573 of the shaped component 576 and the outer circumference of the disc-shaped body 568 are angularly transitioned; the two side walls 573 of the mating component 576 and the end wall 575 also transition through the fillet.
- the output shaft 532 is provided with a recess 577 at least partially receiving the positioning member 562, and a fitting portion matching the shape of the matching member 576 is formed on the inner wall of the recess 577.
- the outer contour of the mating portion is the same as the outer contour of the mating portion 570.
- the mating portion includes a recess 578 that mates with the mating component 576.
- the outer contour of the shaped component 576 can also be other shapes, and can include at least an arc or a polygon or the like.
- the mating portion is formed directly on the disc-shaped body 568.
- a fitting portion matching the outer contour of the disk-shaped body 568 is also formed on the inner wall of the recess 577.
- the outer contour shape of the disc-shaped body 568 may also be other shapes such as a polygon or the like.
- the positioning member 562 is stepped, and the surface of the disc-shaped body 568 extends axially from the step 579.
- the step 579 is a cylindrical step having a radial dimension smaller than the radial dimension of the disc-shaped body 568.
- the thickness of the step 579 is greater than the thickness of the cassette 565.
- the first adapter portion 572 and the second adapter portion 574 are formed by projecting axially from the end faces of the step 579. Moreover, the first adapter portion 572 may have a maximum radial dimension equal to or greater than a maximum radial dimension of the second adapter portion 574.
- the adapter portion further includes a third transition portion 581 disposed axially with respect to the first adapter portion 572 and the second adapter portion 574.
- the third adapter portion 581 extends axially from the second adapter portion 574 and has a maximum radial dimension that is less than a maximum radial dimension of the second adapter portion 574.
- the cross section of the first adapter portion 572 on the plane perpendicular to the output shaft 532 is a regular hexagon, and the connection hole 556 of the working head 534 is just right.
- Match When the working head 534 is mounted to the positioning member 562, its connecting hole 556 is sleeved on the first adapter portion 572 of the positioning member 562 and closely fits to radially position the working head 534. So, set The bit element 562 can transfer the torque on the output shaft 532 to the working head 534 while also fixing the angle of the working head 534 relative to the output shaft 532.
- the cross section of the first adapter portion 572 may also be other shapes, such as a dodecagonal shape matching the dodecagonal working head 534 or the like.
- the first adapter portion 572 has a regular hexagonal cross-section such that the working head 534 can have six fixed positions relative to the output shaft 532.
- the multifunction machine in order to allow quick installation or disassembly of the working head and to provide a stronger axial pressing force, the multifunction machine includes a quick clamping mechanism substantially the same as that of the first embodiment.
- a quick clamping mechanism substantially the same as that of the first embodiment.
- the multifunction machine firstly sets the working head 534 on the positioning component 562, and the connecting hole 556 is sleeved on the first adapter portion 572 of the positioning component 562.
- the compression cone spring 563 and the pressure plate 542 axially press the lower surface of the mounting portion 552 of the working head 534 until the mounting portion 552 of the working head 534 is fixed to the mating surface 560 and the pressure plate. Between 542, the working head 534 is axially fixed. During the mounting process, since the first adapter portion 572 and the coupling hole 556 match each other, the working head 534 does not move arbitrarily.
- the drive mechanism in the present invention is not limited to the structure employed in the above embodiments.
- the second adapter portion 574 of the positioning member 562 and the first adapter portion 572 are different in shape, and can connect at least two working heads having different connection holes. The cooperation between the positioning member 562 and the other working head 600 in the present embodiment will be specifically described below with reference to Figs. 52 to 54 and Figs. 57 to 59.
- the second adapter portion 574 is provided on one axial side of the first adapter portion 572.
- the second adapter portion 574 includes eight bosses 602 extending axially from the first adapter portion 572.
- the bosses 602 extend radially from the center circular table 601, and each of the bosses 602 is independently and circumferentially disposed uniformly.
- the boss 602 has a top surface 603 with a circular arc transition between the top surface 603 and the top surface of the first adapter portion 572.
- the working head 600 has a similar shape to the working head 534, and has a mounting portion 604 and a cutting portion 606 bent from the mounting portion 604.
- the mounting portion 604 is provided with a connecting hole 608.
- the difference is that the connecting hole 608 is different in shape from the connecting hole 556 of the working head 534.
- the attachment aperture 608 is star shaped and mates with the second adapter portion 574 of the positioning element 562.
- the connecting hole The 608 includes eight radially extending circular projections 610 that are continuously connected by curved segments 612 that are oriented toward the centerline of the attachment aperture 608.
- the working head 600 When the working head 600 is installed, the working head 600 is first sleeved on the positioning component 562, and the connecting hole 608 is sleeved on the second adapter portion 574 of the positioning component 562, that is, the circular convex
- the 610 is mated with the boss 602 to radially position the working head 600; then the handle 596 is operated to rotate about the axis of the pivot 590, and the cam portion 594 is in contact with the contact surface 598 of the housing to drive the push rod 586 Moving downward, the groove 592 of the push rod 586 is engaged with the locking member 580; at this time, the operating handle 596 rotates around the axis X of the output shaft 532 in the tightening direction, thereby driving the locking member 580 to rotate.
- the locking member 580 and the fastener 536 are threadedly locked.
- the compression cone spring 563 and the pressing plate 542 axially press the lower surface of the mounting portion 604 of the working head 600 until the mounting portion 604 of the working head 600 is fixed in the fitting.
- the work head 600 is axially fixed.
- the working head 534 does not move arbitrarily.
- the third adapter portion 581 of the positioning member 562 is different in shape from the first and second adapter portions 572 and 574 so that other types of working heads can be connected.
- the cooperation of the positioning member 562 with the other working head 614 in the present embodiment will be specifically described below with reference to Figs. 60 and 61.
- the outer contour of the third adapter portion 581 of the positioning member 562 includes at least a conical surface.
- the working head 614 has a similar shape to the working head 534, and has a mounting portion 616 and a cutting portion 618 extending from the mounting portion 616.
- the mounting portion 616 is provided with a connecting hole 620.
- the difference is that the connecting hole 620 is different in shape from the connecting hole 556 of the working head 534.
- the connecting hole 620 is circular and matches the conical surface of the third adapter portion 581.
- the working head 614 When the working head 614 is installed, the working head 614 is first sleeved on the positioning component 562, and the connecting hole 620 is sleeved on the third adapter portion 581 of the positioning component 562, thereby radially positioning the working head 600.
- the handle 596 is operated to rotate about the axis of the pivot 590, and the cam portion 594 is in contact with the contact surface 598 of the housing, thereby driving the push rod 586 to move downward, so that the recess 592 of the push rod 586 and the locking member 580 is engaged; at this time, the operating handle 596 rotates along the axis X of the output shaft 532 in the tightening direction, thereby causing the locking member 580 to rotate, and the locking member 580 and the fastener 536 are screwed.
- the compression cone spring 563 presses the lower surface of the mounting portion 616 of the working head 614 axially until the mounting portion 616 of the working head 614 is fixed between the mating surface 560 and the pressure plate 542, thereby axially securing the working head 614.
- the positioning component of the present invention can connect the plurality of types of working heads by providing the first and second adapters, and even the third adapter, so that the torque on the output shaft 532 can be further transmitted to different types of working heads. These work heads can be mounted on the output shaft 532 at a specific angle quickly and accurately.
- the positioning component of the present invention is not limited to having only the first, second, and third transition portions, and those skilled in the art will readily recognize that one adapter portion or more mounting portions may be provided, such as the fourth.
- the fifth mounting portion and the like can be connected to a plurality of working heads having different connecting holes.
- the shape of the first adapter portion and the second adapter portion is not limited to the shape defined in the above embodiment, and the outer contour may also be a conical surface or a cylindrical surface, or the first adapter portion may be other polygons or Polygons and the like, and the second adapter portion bumps are not limited to eight, as long as they are more than two, and the specific shape of the bumps may be other such as a cylinder or the like.
- the outer contour of the third adapter is not limited to the conical surface, but may also be a cylindrical surface or other shaped bump.
- the positioning member 562 in the tenth embodiment of the present invention is substantially the same as the positioning member 562 in the ninth embodiment, except that the positioning member 562 is disposed at a position.
- the positioning member 562 is disposed on the pressure plate 542. Therefore, the conical spring 563 is disposed between the pressure plate 542 and the positioning member 562, and the elastic force of the conical spring 563 causes the positioning member 562 to always move axially in the direction in contact with the working head 534.
- a stop ring for the stop positioning member 562 to be disengaged is provided on the pressure plate 542.
- the stop ring is a latch 622 having an opening, and the connecting portion 546 is provided with a card slot. The cassette 622 is received in the card slot to prevent the positioning member 562 from being disengaged from the pressure plate 542.
- the positioning member 562 in this embodiment can also form a separate fastening device with the fastener 536, which can be used to assemble a plurality of working heads to a multifunction machine.
- the fastening device facilitates the assembly of the multifunction machine.
- the fastening device can also be sold as a separate accessory.
- the mating portion 570 includes four evenly-arranged shaped components 576.
- the pressure plate 542 has a matching portion that is shaped to match the shape member 576.
- the mating portion is identical in shape to the shaped portion 570 and is a recess 624 that mates with the mating member 576. As such, the positioning member 562 is mated with the pressure plate 542 so that the torque on the output shaft 532 can be transmitted to the working head 534.
- the working head 534 When the working head 534 is installed, the working head 534 is first sleeved on the positioning component 562, and the connecting hole 556 is sleeved on the first adapter portion 572 of the positioning component 562, and is closely matched. Thereby the working head 534 is positioned radially; then the handle 596 is operated to rotate about the axis of the pivot 590, and the cam portion 594 is brought into contact with the contact surface 598 of the housing, thereby driving the push rod 586 to move downward, so that the push rod 586 The groove 592 is engaged with the locking member 580; at this time, the operating handle 596 is rotated about the axis X of the output shaft 532 in the tightening direction, thereby driving the locking member 580 to rotate, so that the locking member 580 and the fastener 536 The thread is locked.
- the compression cone spring 563 and the pressure plate 542 axially press the lower surface of the mounting portion 552 of the working head 534 until the mounting portion 552 of the working head 534 is fixed between the mating surface 560 and the pressure plate 542, thereby The working head 534 is axially fixed.
- the working head 534 does not move arbitrarily.
- the positioning member 562 in the eleventh embodiment of the present invention is substantially the same as the positioning member 562 in the tenth embodiment, except that the output shaft 532 is directly provided with a threaded blind hole 626 for fastening.
- the member 628 includes a pressure plate 630 and a cylindrical threaded portion 632 extending axially from a central portion of the pressure plate 630.
- the fastener 628 on which the working head 534 is mounted is attached to the output shaft 532; at this time, only the threaded portion 632 of the fastener 628 is connected to the threaded blind hole 626, and then the fastener is rotated in the tightening direction. 628, the working head 534 can be easily fixed between the mating face 560 and the pressure plate 630, thereby axially fixing the working head 534. During the mounting process, since the first adapter portion 572 and the coupling hole 556 match each other, the working head 534 does not move arbitrarily.
- the positioning member 562 is mounted on the output shaft 532 in the ninth embodiment, and the working head 534 can be fixed to the output shaft 532 by the fastener 628 as well.
- the cooperation of the first adapter portion 572 and the working head 534 is illustrated, and the cooperation between the other adapter portions of the positioning component 562 and other different types of working pairs is the same as that of the ninth embodiment. Do not repeat them.
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Abstract
一种多功能机,包括用于安装工作头(34)并驱动所述工作头(34)运动的输出轴(32)、将工作头(34)安装在所述输出轴(32)上的紧固件(36)。所述工作头(34)具有可连接到输出轴(32)的安装部(40),所述输出轴(32)末端具有与所述工作头(34)的安装部(40)配接的驱动部(48)。所述驱动部(48)具有与所述安装部(40)的上表面接触的摩擦面(50)。通过摩擦面(50)与安装部(40)的上表面进行紧密配合,使得多功能机可连接不同类型的工作头(34),大大提高了多功能机的通用性和便利性。
Description
多功能机 技术领域
本发明涉及一种多功能机, 尤其涉及一种可以安装多种不同类型工作头 的多功能机。
背景技术
多功能机是业界常见的手持式的摆动类动力工具, 它的工作原理是输出 轴围绕自身的轴心线做旋转摆动运动, 从而带动安装在输出轴末端的附件工 作头摆动运动。 常见的附件工作头包括直锯片、 圆锯片、 三角形磨砂盘和铲 型刮刀等。 因此, 当用户在输出轴上安装有不同的附件工作头后, 可以实多 种不同的操作功能, 如锯、 切、 磨、 刮等, 以适应不同的工作需求。 传统的 多功能机在工作头和输出轴之间设有用于传递扭矩的形配合机构。 如工作头 上开设有具有八个圆角的星形开口, 且圆角之间连续连接。 对应地, 输出轴 的末端径向凸出延伸有四个圆角型凸起。 将工作头安装至输出轴时, 星形开 口恰好套设在输出轴的圆角型凸起上,再通过螺钉将工作头安装在输出轴上。
然而, 上述多功能机的不足是: 将工作头安装在输出轴上的前提条件是 工作头的星形开口与输出轴上的凸起形状相匹配, 否则, 如若换成具有其它 形状开口的工作头则无法安装在该输出轴上。 因此, 使输出轴可以连接的工 作头的种类受到了限制。
发明内容
本发明要解决的技术问题: 提供一种可连接多种不同类型的工作头的多 功能机。
本发明解决其技术问题所釆用的技术方案: 一种多功能机, 包括用于安 装工作头并驱动所述工作头运动的输出轴、 将工作头安装在所述输出轴上的 紧固件, 所述工作头具有可连接到输出轴的安装部, 所述输出轴末端具有与 所述工作头的安装部配接的驱动部, 所述驱动部具有与所述安装部的上表面 接触的摩擦面。
与现有技术相比, 本发明的有益效果: 通过摩擦面与安装部的上表面进 行紧密配合, 使得多功能机的可连接不同类型的工作头, 大大提高了多功能 机的通用性和便利性, 而且摩擦面和安装部的上表面之间所产生的摩擦力足
够大, 以使在多功能机的工作过程中, 可将输出轴上的摆动扭矩传递到工作 头上, 且不会使工作头出现打滑现象。
优选的, 所述多功能机还包括定位元件和弹性元件, 所述弹性元件促使 所述定位元件始终朝着与工作头相接触的方向轴向移动。
优选的, 所述工作头包括第一工作头和第二工作头, 所述第一工作头包 括与配合面平行的第一中心面和供紧固件穿过的第一连接孔; 所述第二工作 头包括与配合面平行的第二中心面和供紧固件穿过的第二连接孔, 所述定位 元件能够与第一连接孔至少部分相接触且在所述第一中心面内具有第一横截 面; 所述定位元件能够与第二连接孔至少部分相接触且在所述第二中心面内 具有第二横截面, 所述第一横截面与所述第二横截面不相同。 与现有技术相 比, 本发明的有益效果: 定位元件可以在与第一或第二工作头相接触时, 在 对应的中心面上形成具有不相同的横截面, 从而使得该定位元件可以适配多 种不同类型的工作头。
优选的, 所述第一横截面的外轮廓形成第一外接圆, 所述第二横截面的 外轮廓形成第二外接圆, 其中所述第一外接圆与所述第二外接圆的直径大小 不相同。
优选的, 所述第一横截面的形状和所述第二横截面的形状不相同。
优选的,所述第一横截面和所述第二横截面相对于输出轴的位置不相同。 其中第一、 第二横截面的形状至少是圆形、 多边形或椭圆形其中之一。
优选的, 所述定位元件包括供紧固件穿过的中心孔和围绕中心孔设置的 外周面, 所述外周面包括轴向设置的与所述第一连接孔相接触的第一外轮廓 和与所述第二连接孔相接触的第二外轮廓。
优选的, 所述外周面包括至少一个圆锥面, 所述述第一外轮廓和所述第 二外轮廓设于所述圆锥面上。
优选的, 所述外周面至少包括第一圆柱面和第二圆柱面, 所述第一外轮 廓设于所述第一圆柱面上, 所述第二外轮廓第二圆柱面上。
优选的, 所述第一圆柱面和第二圆柱面轴向间断设置或轴向连续设置。 优选的, 所述外周面自第一外轮廓至所述第二外轮廓最大径向尺寸的变 化是线性的。
优选的, 所述外周面自第一外轮廓至所述第二外轮廓最大径向尺寸的变 化是非线性的。
优选的,所述外周面与通过所述中心孔的中心线的纵剖面相交形成交线,
所述交线至少是直线、 曲线或弧线其中之一。
优选的, 所述定位元件为变形件, 所述变形件与第一连接孔相接触且在 所述第一中心面内形成与第一连接孔相切的第一外接圆; 所述变形件与第二 连接孔相接触且在所述第二中心面内形成与第二连接孔相切的第二外接圆。
优选的, 所述定位元件包括用于将所述输出轴上的扭矩传递给工作头的 形配部、 与工作头配接的转接部。
优选的, 所述转接部至少包括与不同形状的连接孔配接的第一转接部和 第二转接部。
优选的, 所述定位元件包括盘状主体, 所述形配部由所述盘状主体的外 圆周径向向外延伸而成, 所述第一转接部和第二转接部自所述盘状主体的一 侧轴向凸伸而成。
优选的, 所述形配部包括至少两个从所述盘状主体的外圆周径向向外延 伸的形配元件。
优选的, 盘状主体的外轮廓在垂直于输出轴的平面上的投影为多边形。 优选的, 所述第二转接部沿轴向设于所述第一转接部的一侧, 且所述第 一转接部与第二转接部的径向尺寸不等。
优选的, 所述第一转接部和第二转接部在垂直于输出轴的平面上的投影 形状不同。
优选的, 所述第一转接部和所述第二转接部至少其中之一的外轮廓为圆 雄面或圆柱面。
优选的, 所述第一转接部的外轮廓在垂直于输出轴的平面上的投影为正 多边形, 所述第二转接部包括至少两个自第一转接部轴向延伸的凸起。
优选的, 所述定位元件还包括相对所述第一转接部和第二转接部沿轴向 设置的第三转接部, 所述第三转接部的径向尺寸小于所述第一转接部或第二 转接部的径向尺寸。
优选的, 所述第三转接部的外轮廓为圆锥面或圆柱面。
优选的, 所述紧固件包括与工作头接触的压板, 所述弹性元件设置在所 述压板和所述定位元件之间。
优选的, 所述紧固件包括与所述工作头相接触的压板, 所述压板上设有 与所述形配部相适配的匹配部, 所述弹性元件设置在所述压板和所述定位元 件之间。
优选的, 所述紧固件上设有止挡所述定位元件轴向脱开的止挡环。
优选的, 所述定位元件设置在所述输出轴内, 所述弹性元件设置在所述 输出轴和所述定位元件之间。
优选的, 所述输出轴上设有与所述形配部相适配的配合部, 所述弹性元 件设置在所述输出轴和所述定位元件之间。
优选的, 所述输出轴上设有止挡所述定位元件轴向脱开的止挡件。
优选的, 多功能机包括定位元件和弹性元件, 弹性元件促使所述定位元 件始终朝着与工作头所述第一连接孔或第二连接孔相接触的方向径向移动。
优选的, 所述工作头包括第一工作头和第二工作头, 所述第一工作头包 括与配合面平行的第一中心面和供紧固件穿过的第一连接孔; 所述第二工作 头包括与配合面平行的第二中心面和供紧固件穿过的第二连接孔, 所述定位 元件包括至少两个周向设置的定位块, 所述至少两个定位块与第一连接孔相 接触且在所述第一中心面上定义了第一横截面; 所述至少两个定位块与第二 连接孔相接触且在所述第二中心面定义了第二横截面, 所述第一横截面和所 述第二横截面相对于所述输出轴的位置不相同。
优选的, 所述摩擦面主要由若干凸肋形成。 优选的, 所述凸肋相对于输 出轴的轴心线径向延伸。
优选的, 所述摩擦面由若干轴向突出的芯轴形成。 优选的, 所述芯轴为 圆锥形或呈圆环状设置。
优选的, 所述摩擦面包括含有摩擦材料的涂覆层。 优选的, 所述涂覆层 主要由金属材料构成。
优选的, 所述驱动部上设有凹陷, 所述多功能机进一步包括与所述凹陷 配合的定心元件。
优选的, 所述定心元件包括第一面、 与第一面相对的第二面、 连接第一 面和第二面的周壁以及供紧固件穿过的中心定位孔, 所述第二面上设有与所 述安装部相配合的形配部。 优选的, 所述第一面为平面。
优选的,所述周壁上均勾设有至少两个与所述凹陷的内壁相接触的隆起。 优选的, 所述定心元件由塑料或金属材料制成。
优选的, 所述定心元件上设有周向均勾设置的膨胀孔。
优选的,所述形配部包括围绕所述中心定位孔自第二面轴向延伸的凸台, 且凸台的外侧壁是正多边形或正多角形。
优选的, 所述形配部包括至少三个凸起, 所述凸起自第二面轴向延伸、 且周向均匀设置, 所述凸起为 自所述中心定位孔径向向外延伸的圆形尖端。
优选的, 所述形配部包括至少三个锁定元件, 所述锁定元件自第二面轴 向延伸、 且周向均勾设置, 所述锁定元件位于中心定位孔之外。
优选的, 所述锁定元件的横截面是梯形、 矩形、 三角形、 弧形、 正方形、 圆形或椭圆形中的任意一种。
一种用于多功能机的定心元件, 所述多功能机包括带动工作头旋转摆动 的输出轴、 将工作头安装在所述输出轴上的紧固件, 所述工作头具有可连接 到输出轴的安装部, 所述输出轴末端设有与所述工作头的安装部配接的驱动 部, 所述驱动部具有与所述安装部的上表面接触的摩擦面及与所述定心元件 配合的凹陷, 其特征在于: 所述定心元件包括第一面、 与第一面相对的第二 面、 连接第一面和第二面的周壁以及供紧固件穿过的中心定位孔, 所述第二 面上设有轴向延伸且与所述安装部相配合的形配部, 且所述第一面和第二面 之间的最大距离不大于所述凹陷的轴向深度。
由于第一面和第二面之间的最大距离不大于凹陷的轴向深度, 如此, 当 定心元件装配在凹陷内时, 不会阻碍输出轴上的摩擦面与工作头上的安装部 的上表面接触。 从而使定心功能与固定功能和 /或转递扭矩的有利分离, 减少 了定心元件的磨损。 相对地, 定心元件可以使用成本相对较低的材料, 根据 具有各种安装部的工作头而设计相应的定心元件。 因此, 在满足多功能机可 以配接各种不同类型的工作头的情况下, 不会增加成本。
一种紧固装置, 用于将多种工作头装配到一种多功能机上, 所述多功能 机包括用于安装工作头并驱动工作头旋转摆动的输出轴, 所述输出轴包括与 工作头配合的配合面; 所述工作头至少包括第一工作头和第二工作头, 其中 所述第一工作头包括与输出轴配接的第一安装部, 所述第一安装部包括与配 合面平行的第一中心面和供紧固件穿过的第一连接孔; 所述第二工作头包括 与输出轴配接的第二安装部, 所述第二安装部包括与配合面平行的第二中心 面和供紧固件穿过的第二连接孔,所述紧固装置包括与输出轴连接的紧固件、 设置在所述紧固件上的定位元件, 其中所述定位元件能够与第一连接孔至少 部分相接触且在所述第一中心面内具有第一横截面; 所述定位元件能够与第 二连接孔至少部分相接触且在所述第二中心面内具有第二横截面, 所述第一 横截面与所述第二横截面不相同。
紧固装置上设有定位元件, 该定位元件可以在与第一或第二工作头相接 触时, 在对应的中心面上形成具有不相同的横截面, 从而使得定位元件可以 适配多种不同类型的工作头。 而且由于提供了起定位作用的定位元件, 从而
使定位功能与固定功能和 /或转递扭矩的有利分离, 减少了定位元件的磨损。 优选的, 所述定位元件为变形件, 所述变形件与第一连接孔相接触且在 所述第一中心面内形成与第一连接孔相切的第一外接圆; 所述变形件与第二 连接孔相接触且在所述第二中心面内形成与第二连接孔相切的第二外接圆。
优选的, 多功能机还包括弹性元件, 弹性元件促使定位元件始终朝着与 所述第一连接孔或第二连接孔相接触的方向轴向移动, 且所述紧固件包括与 工作头接触的压板, 所述弹性元件设置在所述压板和所述定位元件之间。 附图说明
图 1是本发明多功能机的第一实施例中, 头部区域并拆除了部分外壳的 示意图。
图 2是本发明多功能机的第一实施例中, 头部区域并拆除了部分外壳的 立体分解示意图。
图 3是本发明多功能机的第一实施例中, 一种摩擦面的示意图。
图 4是本发明多功能机的第一实施例中, 工作头安装在图 3所示的摩擦 面上的剖示图。
图 5是本发明多功能机的第一实施例中, 工作头与另一种摩擦面配合的 立体分解示意图。
图 6是图 5所示的摩擦面的示意图。
图 7是本发明多功能机的第一实施例中, 工作头与另一种摩擦面配合的 立体分解示意图。
图 8是图 7所示的摩擦面的示意图。
图 9是图 7 中 A-A向的剖示图。
图 10是图 9中 B处的放大图。
图 11是本发明多功能机的第一实施例中,工作头与另一种摩擦面配合的 立体分解示意图。
图 12是本发明多功能机的第二实施例中, 工作头、 输出轴和定心元件的 立体分解示意图。
图 13是本发明多功能机的第二实施例中, 工作头、 输出轴和定心元件的 立体分解示意图, 其中定心元件收容于输出轴的凹陷中。
图 14是图 12所示的定心元件的第一面的示意图。
图 15是图 12所示的定心元件的侧面示意图。
图 16是图 12所示的定心元件的第二面的示意图。
图 17是本发明多功能机的第二实施例中,工作头通过定心元件安装在输 出轴上的剖示图。
图 18是本发明多功能机的第三实施例中, 工作头、 输出轴和定心元件的 立体分解示意图。
图 19是图 18所示的定心元件的第一面的示意图。
图 20是图 18所示的定心元件的侧面示意图。
图 21是图 18所示的定心元件的第二面的示意图。
图 22是本发明多功能机的第四实施例中, 工作头、 输出轴和定心元件的 立体分解示意图。
图 23是图 22所示的定心元件的第一面的示意图。
图 24是图 22所示的定心元件的侧面示意图。
图 25是图 22所示的定心元件的第二面的示意图。
图 26是本发明第五实施例中的多功能机的头部区域的立体分解示意图。 图 27是适用于图 26所示多功能机的第一工作头的立体示意图。
图 28是适用于图 26所示多功能机的第二工作头的立体示意图。
图 29是适用于图 26所示多功能机的第三工作头的立体示意图。
图 30是适用于图 26所示多功能机的第四工作头的立体示意图。
图 31是本发明多功能机的第五实施例中, 定位元件的立体示意图。 图 32是图 31所示定位元件的正视图。
图 33是图 27所示第一工作头与定位元件配合的立体示意图。
图 34是图 28所示第二工作头与定位元件配合的立体示意图。
图 35是图 29所示第三工作头与定位元件配合的立体示意图。
图 36是图 30所示第四工作头与定位元件配合的立体示意图。
图 37是图 26所示多功能机头部区域的另一个角度的立体分解示意图。 图 38是图 26所示多功能机头部区域的剖面示意图, 此时紧固件及第一 工作头还未安装在输出轴上。
图 39是图 26所示多功能机头部区域的剖面示意图, 此时第一工作头处 于锁紧过程中。
图 40是图 26所示多功能机头部区域的剖面示意图, 此时第一工作头被 锁紧在输出轴上。
图 41是图 40中沿 C-C方向的剖视图。
图 42是本发明多功能机的头部区域的剖面示意图,此时第二工作头被锁
紧在输出轴上。
图 43是图 42中沿 D-D方向的剖视图。
图 44是本发明多功能机的头部区域的剖面示意图,此时第三工作头被锁 紧在输出轴上。
图 45是本发明多功能机的头部区域的剖面示意图,此时第四工作头被锁 紧在输出轴上。
图 46是本发明第六实施例中的多功能机, 头部区域的剖面示意图, 此时 紧固件及第一工作头还未安装在输出轴上。
图 47是图 46所示多功能机的头部区域的剖面示意图, 此时第一工作头 被锁紧在输出轴上。
图 48是本发明第七实施例中的紧固件和定位元件的立体分解图。
图 49是通过图 48 中的紧固件和定位元件将第一工作头锁紧在输出轴上 的示意图。
图 50是图 49中沿 G-G方向的剖视图。
图 51是第二工作安装在输出轴上时的截面示意图。
图 52是本发明第九实施例中的多功能机的头部区域的立体分解示意图。 图 53是本发明第九实施例中的定位元件的立体示意图。
图 54是本发明第九实施例中的定位元件的主视图。
图 55是本发明第九实施例中的定位元件的俯视图。
图 56是图 53所示的定位元件与一种工作头配合的示意图。
图 57是图 52所示多功能机头部区域的剖面示意图, 此时工作头被锁紧 在输出轴上。
图 58是图 52所示的多功能机安装第二种工作头的立体分解示意图。 图 59是图 52所示的定位元件与第二种工作头配合的示意图。
图 60是图 58所示多功能机头部区域的剖面示意图, 此时第二种工作头 被锁紧在输出轴上。
图 61是图 52所示的多功能机安装第三种工作头的立体分解示意图。 图 62是图 61所示多功能机头部区域的剖面示意图, 此时第三种工作头 被锁紧在输出轴上。
图 63是本发明第十实施例中的多功能机的头部区域的立体分解示意图。 图 64是本发明第十实施例中的多功能机的头部区域的立体分解示意图, 此时定位元件与紧固件安装在一起。
图 65是图 63所示多功能机头部区域的剖面示意图, 此时第一种工作头 被锁紧在输出轴上。
图 66是本发明第十一实施例中的多功能机的头部区域的剖面示意图,此 时第一种工作头未安装在输出轴上。
具体实施例
本发明涉及一种可适配多种工作头的多功能机。 其中现有的工作头种类 很多, 本发明的具体实施例中仅列举几种典型的工作头以说明本发明的创作 构思。 当然, 未列举到的工作头, 同样适用于本发明。 下面结合附图与具体 实施例对本发明作进一步说明。
如图 1 所示, 该多功能机包括机壳 30、 安装在机壳 30 内的马达 (未图 示)、 由马达驱动的输出轴 32及安装在输出轴 32下方的工作头 34。 一紧固 件 36穿过工作头 34后连接在输出轴 32的末端, 从而将工作头 34 固定在输 出轴 32上, 并可在输出轴 32的带动下运动。
如图 1和图 2所示, 输出轴 32纵向设置于机壳 30的内部, 其末端延伸 出机壳 32—定距离。 输出轴 32上安装有一拨叉件 38 , 马达转动时, 可带动 一偏心装置 (未图示) 转运, 该偏心装置进而带动拨叉件 38 实现旋转摆动, 从而使输出轴 32做旋转摆动运动。 输出轴 32的末端设有直径较大的连接法 兰 33。 连接法兰 33上设有供紧固件 36穿过的圆孔 35。 连接法兰 33与输出 轴 32—体成型, 也可以固定安装在输出轴 32上。 在本发明中该连接法兰 33 固定安装在输出轴 32上 (可参见图 4 )。
此处需要指出, 输出轴 32上可以直接设置有螺紋盲孔, 紧固件 36为紧 固螺栓, 包括环状压板 58 和自压板 58 的中部轴向延伸的杆部 60。 杆部 60 包括与压板 58连接的连接部 37和与其相连的螺紋部 39。 安装工作头时, 只 需要将紧固件 36穿工作头 34并与螺紋盲孔螺紋连接, 从而将工作头固定在 输出轴上。 但在本实施例中, 为了可以快速安装或拆卸工作头, 并能够提供 更强的轴向压紧力, 该多功能机设有快速夹紧机构, 这在后面详细阐述。
如图 2所示, 工作头 34为一种直锯片, 对本领域技术人员来说, 很容易 想到, 工作头 34也可以是其它附件, 如圆锯片、 砂盘、 刮刀等。 工作头 34 为金属材质, 其包括可连接在连接法兰 33上的安装部 40和切割部 42。 安装 部 40上开设有供紧固件 36穿过的连接孔 44 , 本实施例中, 连接孔 44为正 十二角形, 当然, 在这里, 连接孔 44也可以是其它正多角形、 正多边形、 圆 形等任意形状。 切割部 42末端则设有具有切割功能的锯齿 46。
输出轴 32的末端的连接法兰 33上设有驱动部 48。 驱动部 48 包括与工 作头 34 的安装部 40 的上表面相接触的配合面。 当工作头 34 固定在输出轴 32上时, 工作头 34的上、 下表面分别贴覆在紧固件 36和配合面之间。 在这 里, 配合面与工作头 34上表面所产生的摩擦力足够大, 以使在多功能机的工 作过程中, 可将输出轴 32上的摆动扭矩传递到工作头 34上, 且不会使工作 头出现打滑现象。
如图 3所示, 配合面可以是光面或摩擦面, 在本实施例中为摩擦面 50。 摩擦面 50由若干规则排布的凸肋 52形成。 这些凸肋 52大致呈扇形, 并由自 径向向内发射相交于圆孔 35的外边缘。且其横截面可以是梯形、矩形、半圆、 椭圆等等形状, 而且顶端也可以较尖锐。 在本实施例中, 其横截面为矩形。 当然, 这些凸肋 52也可以是由任意与圆孔 35 同心的同心圆径向向外发射, 或者是按网格的方式排布。 更进一步的, 上述凸肋 52还可以设置为曲线状, 如" S "状, 并可不规则地分布在输出轴上。
如图 4所示, 快速夹紧机构包括锁紧件 54和可围绕输出轴 32的轴线 X 转动的驱动机构 56。 沿一个方向旋转驱动机构 56时, 能够驱动锁紧件 54和 紧固件 36螺纹锁紧; 然后沿相反方向旋转驱动机构 56时, 则驱动锁紧件 54 和紧固件 36松开。
锁紧件 54收容在输出轴 32的腔体内。 该锁紧件 54大致呈圆环状, 能够 在腔体内 自 由旋转但不会产生轴向位移,其中部轴向开设有与紧固件 36螺纹 部 39连接的螺纹孔。 紧固件 36的连接部 37的横截面大致为正方形, 轴出轴 32设有收容该连接部 37的通孔 62。 该通孔 62的横截面大致也为正方形, 当 连接部 37穿设在通孔 62中, 使得紧固件 36不能相对输出轴 32转动。 因此, 进一步的防止了工作头出现打滑现象。
驱动机构 56 包括用于与锁紧件 54啮合并驱动锁紧件 54转动的推杆 64 和操作推杆 64运动的操作件 66。 推杆 64的顶部安装有枢轴 68、 底部轴向开 设有凹槽 70。 其中, 枢轴 68 的轴线垂直于输出轴 32的轴线 X。 凹槽 70套 设在锁紧件 54 的外圆周上并通过啮合装置带动锁紧件 54 转动。 操作件 66 通过枢轴 68枢接在推杆 64的顶端。 其相对枢轴 68 的一侧设有凸轮部 72 , 另一侧为延伸有大致垂直于凸轮部 72的手柄 74。 其中当旋转手柄 74使其围 绕枢轴 68的轴线旋转时, 凸轮部 72会与壳体的上表面 73相接触, 从而促使 推杆 64上、 下移动。
安装工件时, 只需操作手柄 74 , 使其围绕枢轴 68 的轴线旋转, 进而带
动推杆 64向下移动, 使得推杆 64的凹槽 70与锁紧件 54啮合, 这时, 可以 操作手柄 74围绕输出轴 32的轴线 X沿着旋紧的方向旋转, 从而带动锁紧件 54—起转动, 使锁紧件 54和紧固件 36的螺紋部 39锁紧, 从而将工作头 34 固定在输出轴 32上。
需要拆卸工作头 34时, 只需操作手柄 74 , 带动推杆 64向下移动, 使得 推杆 64的凹槽 70与锁紧件 54啮合, 这时, 操作手柄 74围绕输出轴 32的轴 线 X沿着旋松的方向旋转, 从而带动锁紧件 54—起转动, 直到锁紧件 54与 紧固件 36完全脱开螺紋连接, 此时可将紧固件 36从输出轴 32中拆下, 取出 工作头 34。 由于工作头 34的安装部 40上的连接孔 44为封闭的, 因此, 需 要将锁紧件 54与紧固件 36完全脱离开, 以将其从输出轴 32上取下, 再将紧 固件 36穿过工作头 34的连接孔 44后安装至输出轴 32 内。 当然, 也可以将 工作头的开口加工成非封闭的, 留有可穿过紧固件的杆部的缺口。 此种情况 无需将紧固件完全从锁紧件上拆下, 只需拧松锁紧件, 使紧固件与输出轴的 之间留出可供工作头的安装部穿过的间隙即可。
如图 2、 图 3和图 4所示, 多功能机在使用工作头时, 首先将工作头 34 放置在输出轴 32的下方,并使工作头 32的安装部 40的上表面贴覆在输出轴 32 的凸肋 52上。 凸肋 52 既可以在轴向方向又可在圆周方向上在输出轴 32 和工作头 34之间实现大的传力连接, 使传递的扭矩足够大, 从而保证工作头 34与输出轴 32之间不会出现相对滑动。
工作时, 输出轴 32在马达(未图示) 的带动下作旋转摆动, 由于输出轴 32上设有由凸肋 52形成的摩擦面 50的存在, 使输出轴 32与工作头 34的安 装部 40的上表面之间具有足够大的摩擦力, 从而将输出轴 32输出的摆动扭 矩进一步传递给工作头 34 , 进而带动工作头 34作摆动运动。
上述相邻凸肋 52之间具有较大空隙, 同样可以收容工作头 34的安装部 40上的污物和灰尘, 从而也可以保证即使在工作头受污染的状态下, 凸肋 52 和工作头 34的安装部 40的上表面之间有良好的接触。
当然, 摩擦面还可以是其它形状。 如图 5至图 6所示, 摩擦面 50a与摩 擦面 50不同之处在于, 该摩擦面 50a的凸肋 52a并非是完整的肋条, 而是被 若干与输出轴 32的轴线 X 同心的圆环隔断, 如此, 摩擦面 50a是由若干规 则排布的凸起形成。 这样, 在不影响摩擦面 50 a和安装部 40的上表面之间的 摩擦力时, 可以收容更多工作头 34的安装部 40上的污物和灰尘。 工作时, 输出轴 32在马达 (未图示) 的带动下作旋转摆动, 由于输出轴 32设有摩擦
面 50a , 使输出轴 32与工作头 34的安装部 40的上表面之间具有足够大的摩 擦力, 从而将输出轴 32输出的摆动扭矩传递给工作头 34 , 进而带动工作头 34作摆动运动。
如图 7至图 10所示,摩擦面 50b与摩擦面 50不同之处在于,摩擦面 50b 是由若干规则排布的芯轴 76形成。 该若干芯轴 76大致呈圆锥状, 且各芯轴 76的周围分别设有环形凹处 78。 将工作头 34安装在输出轴 32上时, 其芯轴 76的顶端 4民压在工作头 34的安装部 40的上表面。 芯轴 76既可以在轴向方 向又可在圆周方向上在输出轴 32和工作头 34之间实现大的传力连接, 使传 递的扭矩足够大, 从而保证工作头 34与输出轴 32之间不会出现相对滑动。 工作时, 输出轴 32在马达 (未图示) 的带动下作旋转摆动, 由于输出轴 32 设有由芯轴 76形成的摩擦面 50b的存在,使输出轴 32与工作头 34的安装部 40 的上表面之间具有足够大的摩擦力, 从而将输出轴 32输出的摆动扭矩进 一步传递给工作头 34 , 进而带动工作头 34作摆动运动。
上述凹处 78可以收容工作头 34的安装部 10上的污物和灰尘,从而保证 了即使在工作头受污染的状态下, 芯轴 76和安装部 40的上表面之间也有良 好的接触。 上述芯轴 76也可设置为方形、 矩形等其它的几何形状, 只要可以 形成较粗糙的摩擦面即可;而且上述芯轴 76可以规则或不规则地排布于输出 轴 32上。
如图 11所示, 摩擦面 50c与摩擦面 50不同之处在于, 该摩擦面 50c包 括含有摩擦材料的涂覆层 80 , 将工作头 34安装在输出轴 32上时, 工作头 34 的安装部 40的上表面与涂覆层 80贴覆。涂覆层 80既可以在轴向方向又可在 圆周方向上在输出轴 32和工作头 34之间实现大的传力连接, 使传递的扭矩 足够大, 从而保证工作头 34与输出轴 32之间不会出现相对滑动。 工作时, 输出轴 32在马达 (未图示) 的带动下作旋转摆动, 由于输出轴 32设有涂覆 层 80 , 使输出轴 32与工作头 34的安装部 40的上表面之间具有足够大的摩 擦力, 从而将输出轴 32输出的摆动扭矩进一步传递给工作头 34 , 进而带动 工作头 34作摆动运动。
当然在输出轴 32上也可不设涂覆层 80 , 而在输出轴 32 的连接法兰 33 的末端直接打磨出粗糙摩擦面即可。
综上所述, 摩擦面与工作头的上表面之间所产生的摩擦力足够大, 可将 输出轴上的摆动扭矩传递到工作头上, 且不会使工作头出现打滑现象。 由于 是通过摩擦面与工作头的上表面进行紧密配合, 从而工作头的连接孔可以是
其它任意形状。 因此, 通过设置具有摩擦面的输出轴, 可以使多功能机的连 接的不同种类的工作头均可以牢固的安装在输出轴上。 大大提高了多功能机 的通用性和便利性。
如图 12至图 17所示, 安装工作头时, 为了可以更加方便、 快速的将工 作头安装到位, 即工作头的连接孔的中心线与输出轴 32 的轴线 X重合, 该 多功能机还可以适配一定心元件 82。
本发明的第二实施例与第一实施例结构基本相同, 所不同之处在于, 输 出轴 32的连接法兰 33上设有可与定心元件 82适配的凹陷 84。 凹陷 84 自摩 擦面 50轴向向内延伸, 轴向深度为 H。 凹陷 84具有圆形的内壁 98 , 其中心 线与输出轴 32的轴线 X重合。 在本实施例中, 凹陷 84的截面为圆形, 当然 也可以是矩形、 正多边形、 正多角形等。 因此, 与之相适配的定心元件 82 的形状也可以是矩形、 正多边形、 正多角形等。
定心元件 82安装在输出轴 32和工作头 34之间。 该定心元件 82大致呈 圆柱体状, 其包括面对凹陷 84的第一面 86、 与工作头 34面对的第二面 88、 连接第一面 86和第二面 88的周壁 90以及供紧固件 36穿过的中心定位孔 92。
其中, 第一面 86与输出轴 32的凹陷 84相对, 其上可以设置一些摩擦面 或与凹陷 84形配的凸起。 但在本实施例中, 第一面 86可以是平面, 无需设 置摩擦面或凸起。 特别地, 第二面 88与工作头 34相对, 其上设有与工作头 34的安装部 40相配合的形配部 94。 当形配部 94恰好与工作头 34的安装部 40配接, 如此, 就可以方便工作头 34定心。
在本实施例中, 第一面 86和第二面 88平行设置, 两者之间的距离为 L。 第一面 86和第二面 88之间的距离 L不大于凹陷 84的轴向深度 H。 如此, 当定心元件 82装配在凹陷 84 内时, 不会阻碍工作头 34的安装部 40的上表 面与摩擦面 50相接触。 当然, 第一面 86和第二面 88也可以不平行设置, 但 两者之间的最大距离不能大于凹陷 84的轴向深度 H。
为了定心元件 82可以适配多种工作头, 所以定心元件 82的直径范围一 般在 22至 30毫米内, 可以是 25毫米、 27毫米等。
形配部 94为 自第二面 88轴向延伸的空心的凸台 96 , 其中凸台 96 围绕 中心定位孔 92径向向外延伸。 在本实施例中, 凸台 96的外侧壁是正六边形, 正好与工作头 34的正十二角形连接孔 44配接。
可以理解, 当工作头的连接孔发生变化时, 形配部也可以是与工作头的 连接孔配接的其它形状。在这里,凸台 96的外侧壁还可以是其它的正多边形、
正多角形、 圆形或是其它非规则形状。
定心元件 82可以由塑料或金属材料制成。 在本实例中, 定心元件 82是 由塑料制成。
为了使得定心元件 82与凹陷 84的内壁 98可以更好的贴合。在定心元件 82的周壁 90上均匀设有至少两个与凹陷 84的内壁 98相接触的隆起 100。
在本实施例中, 周壁 90上共设有四个隆起 100。 但隆起 100的个数可以 是任意的; 而且, 该隆起 100即可以规则地分布, 也可以不规则地分布在周 壁 90上。
定心元件 82上设有周向均勾设置的膨胀孔 102。 膨胀孔 102即可以在将 定心元件 82装配在凹陷 84 内时使定心元件 82起到一定变形,从而便于安装 定心元件 82 ; 也可以在将定心元件 82从凹陷 84 内拆卸下来的时候, 供操作 者借用工具将定心元件 82扣出。
所以膨胀孔 102的个数可以是任意的。 且膨胀孔 102即可以是贯穿第一 面 86和第二面 88的通孔, 也可以是不贯穿盲孔。 而且, 该膨胀孔 102即可 以规则地均匀分布, 也可以不规则地分布在第一面 86或第二面 88上。
在本实施例中,为了使得膨胀孔 102可以起到更好变形作用,膨胀孔 102 的大小、 位置可以设定为: 膨胀孔 102的位置与隆起 100的位置在周向上一 一对应。膨胀孔 1 02的在延伸方向的长度比隆起 100在延伸方向的长度更长。 膨胀孔 102的中心线所围成的圆与中心定位孔 92同心,且膨胀孔 1 02所在的 圆的半径是中心定位孔 92的半径的 2倍。
如图 12、 图 13和图 17所示, 将工作头 34安装在输出轴 32上时, 首先 将定心元件 82安装在凹陷 84 内, 再将工作头 34套设到定心元件 82上, 并 使工作头 34的安装部 40与定心元件 82的形配部 94相配接, 从而使得工作 头的连接孔 44的中心线与输出轴 32的轴线 X重合; 然后, 将紧固件 36穿 过连接孔 44、 中心定位孔 92进而与锁定件的螺紋孔配合; 最后, 操作手柄 74 , 使其围绕枢轴 68的轴线旋转, 进而带动推杆 64向下移动, 推杆 64的凹 槽 70与锁紧件 54啮合, 这时, 可以操作手柄 74围绕输出轴 32的轴线 X沿 着旋紧的方向旋转, 从而带动锁紧件 54—起转动, 使锁紧件 54和紧固件 36 螺紋锁紧, 从而将工作头 34 固定在输出轴 32上。
将定心元件 82装配在凹陷 84 内, 定心元件 82可以紧密的与凹陷 84配 合, 从而使其相对于凹陷 84很难转动; 当然, 定心元件 82也可以与凹陷 84 之间具有较大的空隙, 使其可以方便的相对于凹陷 84转动。 这是因为, 摩擦
面 50与工作头 34的安装部 40的上表面之间所产生的摩擦力足够大,而且摩 擦面 50既在轴向方向又在圆周方向上保证了工作头 34的安装部 40相对于输 出轴 32不会相对滑动; 再加上锁紧件 54和紧固件 36螺紋锁紧, 从而可以将 工作头 34牢固地安装在输出轴 32上。所以定心元件 82即使在安装时可以相 对于凹陷 84转动, 但在通过锁紧件 54和紧固件 36 螺紋锁紧后, 定心元件 82会与工作头 34—起随着输出轴 32作摆动运动。
现有技术中, 通过输出轴上的凸起和工作头的星形开口相匹配, 将工作 头固定安装在输出轴上。 这样, 凸起和开口共同起到定心功能、 固定功能和 转矩功能, 如此, 就会导致凸起和开口磨损的非常快。 而本发明中, 定心元 件 82 用于定心作用, 从而使得定心功能与固定功能和 /或转矩功能的有利分 离。 因此, 可以减少定心元件 82、 摩擦面 50和工作头 34的连接孔 44等的 磨损。
相对地, 定心元件 82可以使用成本相对较低的材料, 根据具有各种安装 部的工作头而设计相应的定心元件, 因此, 在满足多功能机可以配接各种不 同类型的工作头的情况下, 不会增加成本。
而且由于定心元件 82相对于凹陷 84可以转动, 从而可以根据需要方便 调节工作头 34相对于输出轴 32的角度位置。
本实施例中, 摩擦面 50是若干凸肋 52形成。 当然, 第一实施例其它摩 擦面也同样适用。
本发明的定心元件并不限于第二实施例中的描述, 下面具体描述一下其 它形状的定心元件。
如图 18、 图 19、 图 20和图 21所示, 本发明的第三实施例, 工作头 34b 与第二实施例中的工作头 34 结构基本相同, 同样具有安装部 40b 和切割部 42b , 安装部 40b上开设有连接孔 44b。 不同之处在于, 连接孔 44b的形状与 工作头 34的连接孔 44形状不同。 该连接孔 44b 包括八个径向延伸的圆形隆 起 104b , 相邻圆形隆起 104b之间通过的曲线段 106b连续连接。
相对于连接孔 44b的变化, 定心元件 82b也与第二实施例中的定心元件 82有所不同。 其中定心元件 82b的第一面 86b、 隆起 100b和膨胀孔 102b与 第二实施例中的第一面 86、隆起 100和膨胀孔 102结构相同。不同之处在于, 第二面 88b设置的与工作头 34b的安装部 40b相配合的形配部 94b与形配部 94不同。
在本实施例中, 形配部 94b 包括自第二面 88b轴向延伸的且周向均匀设
置的四个凸起 108b , 每个凸起 108b均为 自中心定位孔 92b的外边缘径向向 外延伸的圆形尖端。凸起 108b正好与工作头 34b的连接孔 44b上的圆形隆起 104b和曲线段 106b相配接, 从而使得工作头 34b的连接孔 44b的中心线与 输出轴 32的轴线 X重合, 起到定心作用。
可以理解, 工作头 34b的圆形隆起 104b并不限于八个, 只要大于在两个 以上即可, 且相邻圆形隆起之间通过曲线段相互连续连接。 相对应地, 形配 部 94b的凸起 108b也并限于四个, 只要大于两个以上即可。 当然, 最好是圆 形隆起 104b是凸起 108b的整数倍。
当然, 凸起 108b也可以不设置成圆形尖端, 而为矩形、梯形等其它形状, 只需凸起 108b 的形状可与圆形隆起 104b或曲线段 106b相配即可。 且凸起 108b也可以根据需要, 无需均匀设置。
如图 18所示,将工作头 34b安装在输出轴 32上时,首先将定心元件 82b 安装在凹陷 84 内, 再将工作头 34b套设到定心元件 82b上, 并使工作头 34b 的安装部 40b与定心元件 82b的形配部 94b相配接, 从而使得工作头的连接 孔 44b 的中心线与输出轴 32的轴线 X重合; 然后参照上述方法, 通过快速 夹紧机构将将工作头 34 固定在输出轴 32上。
工作时, 输出轴 32在马达(未图示) 的带动下作旋转摆动, 由于输出轴 32设有由凸肋 52形成的摩擦面 50的存在, 使输出轴 32与工作头 34b的安 装部 40b的上表面之间具有足够大的摩擦力,从而将输出轴 32输出的摆动扭 矩进一步传递给工作头 34b , 进而带动工作头 34b作摆动运动。
本实施例中, 摩擦面 50是若干凸肋 52形成。 当然, 第一实施例其它摩 擦面也同样适用。
如图 22、 图 23、 图 24和图 25所示, 本发明的第四实施例, 工作头 34c 与第二实施例中的工作头 34 结构基本相同, 同样具有安装部 40c 和切割部 42c , 安装部 40c上开设有连接孔 44c。 不同之处在于, 连接孔 44c的形状与 工作头 34的连接孔 44形状不同。 该连接孔 44c包括十二个间隔设置在一个 圆周上的孔 110c和供紧固件 36穿过的通孔 l l l c。
相对于连接孔 44c的变化, 定心元件 82c也与第二实施例中的定心元件 82有所不同。 其中定心元件 82bc的第一面 86c、 隆起 100c和膨胀孔 102c与 第二实施例中的第一面 86、 隆起 100和膨胀孔 102b结构相同。 不同之处在 于, 第二面 88c设置的与安装部 40c相配合的形配部 94c与形配部 94不同。
在本实施例中, 形配部 94c 包括自第二面 88c轴向延伸的且周向均匀设
置的十二个锁定元件 112c, 每个锁定元件 112c设置在中心定位孔 92c之外。 且十二个锁定元件 112c正好与工作头 34b的十二个孔 110 c相配接, 从而使 得工作头 34c 的连接孔 44c的中心线与输出轴 32的轴线 X重合, 起到定心 作用。
可以理解, 工作头 34c上的连接孔 44c并不限于十二个的孔 110 c, 只要 大于两个以上即可。相对应地,形配部 94c的锁定元件 112c也并限于十二个, 只要大于两个以上即可, 但最好与孔 110c之间成倍数关系。 且最好是孔 110 c 的个数是锁定元件 112c个数的整数倍。 当然, 锁定元件 112c也可以根据 需要, 无需均匀设置。
在本实施例中, 孔 110c的截面为梯形, 相应地, 形配部 94c的锁定元件 112c 的截面也为梯形。 而为了装卸方便, 锁定元件 112c 具有至少一个用于 支持推插过程的倒角, 并且工作头 34c通过锁定元件 112c和孔 110c的共同 作用, 起到定心作用。
对于本领域技术人员来说, 很容易理解, 锁定元件 112c和孔 110c的横 截面形状并不限于梯形, 也可以是矩形、 三角形、 弧形、 正方形、 圆形或椭 圆形中一种。
如图 22所示,将工作头 34c安装在输出轴 32上时,首先将定心元件 82c 安装在凹陷 84 内, 再将工作头 34c套设到定心元件 82c上, 并使工作头 34c 的安装部 40c与定心元件 82c的形配部 94c相配接, 从而使得工作头 34c的 连接孔 44c 的中心线与输出轴 32 的轴线 X重合; 然后参照上述方法, 通过 快速夹紧机构将将工作头 34c 固定在输出轴 32上。
工作时, 输出轴 32在马达(未图示) 的带动下作旋转摆动, 由于输出轴 32设有由凸肋 52形成的摩擦面 50的存在, 使输出轴 32与工作头 34c的安 装部 40c的上表面之间具有足够大的摩擦力,从而将输出轴 32输出的摆动扭 矩进一步传递给工作头 34c, 进而带动工作头 34c作摆动运动。
本实施例中, 摩擦面 50是若干凸肋 52形成。 当然, 第一实施例其它摩 擦面也同样适用。
可以理解的是, 针对连接孔 44c 包括十二个间隔设置在一个圆周上的孔 110c和供紧固件 36 穿过的通孔 lllc。 本发明实施第二实施例中, 定心元件 82也可以适配。 定心元件 82的空心的凸台 96的外侧壁可以是圆形。 而通孔 111c正好与凸台 96相配接, 从而使得工作头 34c的连接孔 44c 的中心线与 输出轴 32的轴线 X重合, 起到方便安装工作头的作用。
为了可以更加方便、 快速的将不同种工作头安装到位, 多功能机还可以 适配定位元件和弹性元件。 弹性元件用于促使定位元件始终朝着与工作头相 接触的方向轴向移动或径向移动。
图 26至图 45所示为本发明的第五实施例。 本发明的第五实施例与第二 实施例结构基本相同, 相同之处不赘述, 下面就不同之处详细说明。
具体请参见图 26 , 紧固件 236的压板 242上连接有隔热套 250。 该隔热 套 250 包覆在压板 242上, 防止在使用一段时间后, 在需要更换工作头时, 由于输出轴 232上的热量传递到压板 242上而对操作者造成伤害。隔热套 250 的周向上均匀的设有卡钩 252 , 压板 242上设有卡槽 254。 通过卡钩 252卡设 在卡槽 254中, 从而将隔热套 250包覆在压板 242上。
多功能机包括与工作头配合的定位元件 256。 该定位元件 256可以与具 有不同最小内径的连接孔的工作头相适配, 从而能在安装不同种类的工作头 时, 都可以方便、 快速的将工作头安装到位。 即使得不同种类的工作头的连 接孔的中心线都能与输出轴 232的轴线 X大致重合。 当然, 如本领域技术人 员可以理解的, 在这里, 工作头的连接孔的中心线与输出轴的轴线 X也可以 不重合, 两者具有一定距离也同样可以满足方便方便、 快速的将工作头安装 到位。
多功能机还包括弹性元件, 弹性元件的弹性力促使定位元件 256始终朝 着与第一工作头 234a相接触的方向轴向移动。
在本实施例中, 定位元件 256套设在紧固件 236上, 弹性元件设置在压 板 242和定位元件 256之间。 在这里, 弹性元件是锥簧 257 , 而锥簧 257在 被压缩时所占空间比较小。 可以理解, 该弹性元件也可以压簧等。 而为了防 止定位元件 256轴向脱开, 在紧固件 236上设有止挡定位元件 256脱开的止 挡环 259。
当然, 将定位元件 256套设在紧固件 236上, 且在两者中间设置弹性元 件从而构成一个独立的紧固装置, 该紧固装置可以用于将多种工作头装配到 一种多功能机上。 同样, 为了防止定位元件 256轴向脱开, 在紧固件 236上 设有止挡定位元件 256脱开的止挡环 259。 作为一个独立的组件, 该紧固装 置可以方便安装工作头。 当然, 该紧固装置也可以作为一个独立的附件出售。
如本领域技术人员所熟知, 定位元件 256也可以设置在输出轴 232 内, 那么弹性元件则设置在输出轴 232和定位元件 256之间。
图 27至图 30所示为清楚表述本发明的第五实施例, 列举了几种不同类
型的工作头。
请参见图 27所示, 第一工作头 234a为一种直锯片, 其包括第一安装部 258a和第一切割部 260a , 其中第一安装部 258 a用于连接到输出轴 232上。 第一安装部 258a上开设有供紧固件 236 穿过的第一连接孔 262a , 该第一连 接孔 262a是正十二角形, 其最小内切圆的直径为 dl。 第一切割部 260a末端 则设有具有切割功能的锯齿 264a。
请参见图 28所示, 第二工作头 234b为一种直锯片, 其包括第二安装部 258b和第二切割部 260b , 其中第二安装部 258b用于连接到输出轴 232上。 第二安装部 258b上开设有供紧固件 236穿过的第二连接孔 262b , 该第二连 接孔 262b是圆形, 其直径为 d2。 第二切割部 260b末端则设有具有切割功能 的锯齿 264b。
请参见图 29所示, 第三工作头 234c为一种直锯片, 其包括第三安装部 258c和第三切割部 260c , 其中第三安装部 258c用于连接到输出轴 232上。 第三安装部 258c上开设有供紧固件 236 穿过的第三连接孔 262c , 该第三连 接孔 262c是具有八个圆角的星形开口, 且圆角之间连续连接。 其最小内切圆 的直径与第二连接孔的直径相等, 为 d2。 第三切割部 260c末端则设有具有 切割功能的锯齿 264c。
请参见图 30所示, 第四工作头 234d为一种直锯片, 其包括可连接在输 出轴 232上的第四安装部 258d和第四切割部 260d。 第四安装部 258d上开设 有供紧固件 236 穿过的第四连接孔 262d , 该第四连接孔 262d是圆形, 其直 径为 d3。 第四切割部 260d末端则设有具有切割功能的锯齿 264d。 不过为了 方便安装, 第四连接孔 262d为设有缺口的非封闭圆孔。
如图 31和图 32所示,定位元件 256具有供紧固件 236穿过的中心孔 265 以及围绕中心孔 265设置的周壁 266。 其中周壁 266 包括与工作头的连接孔 配合用于工作头定位的外周面 268。
外周面 268沿轴向至少包括具有第一最大径向尺寸的第一外轮廓和具有 第二最大径向尺寸的第二外轮廓, 其中第一最大径向尺寸与第二径向尺寸不 相等。 因此, 第一外轮廓和第二外轮廓适用于与具有不同最小内径的连接孔 的工作头至少部分相接触, 从而用于不同种类的工作头定位。
第一外轮廓或第二外轮廓与相应的连接孔的最小内径接触时可以是面与 面接触。 如若是面与面接触, 这样接触面比较大, 定位比较可靠。 当然, 第 一外轮廓或第二外轮廓与相应的连接孔的最小内径也可以是点接触。 其中接
触点至少为三个, 就可以实现相应的工作头的定位。 优选的, 该至少三个接 触点至少组成一个直角三角形或锐角三角形。
外周面 268 自第一外轮廓至第二外轮廓最大径向尺寸的变化可以是线性 的, 也可以是非线性的。
优选的, 外周面 268 包括至少两个不同最大径向尺寸的圆柱面, 至少两 个圆柱面用于与具有不同最小内径的连接孔的工作头至少部分相接触。
在本实施例中, 外周面 268 包括第一圆柱面 270和第二圆柱面 272。 其 中若干相同的具有第一最大径向尺寸 D 1 的第一外轮廓 274形成了第一圆柱 面 270 ;若干相同的具有第二最大径向尺寸 D2的第二外轮廓 278形成了第二 圆柱面 272。
在这里, 第一外轮廓 274和第二外轮廓 278的形状是一样的, 均是圆形。 可以理解, 如果第一外轮廓和第二外轮廓的形状不一样也同样可以实现相应 的工作头的定位。
在本实施例中, 第一外轮廓 274和第二外轮廓 278的形状都是圆形。 对 于本领域技术人员来说, 很容易理解, 第一外轮廓 274和第二外轮廓 278的 形状并不限于圆形, 也可以是多边形或椭圆形等其它形状。
在本实施例中, 第一圆柱面 270和第二圆柱面 272是轴向间断设置的。 外周面 268还包括用于连接第一圆柱面 270和第二圆柱面 272的连接面, 该 连接面可以是具有线性变化的圆锥面或内凹、 外凸等曲面; 也可以是非线性 变化的多个折弯面形成。 在这里, 连接面是圆锥面 280 , 该圆锥面 280是由 沿轴向方向具有不同最大径向尺寸的外轮廓形成。 因此, 不同的外轮廓可以 适配具有不同最小内径的连接孔的工作头。 如本领域技术人员可以想到的, 外周面 268上设置至少一个圆锥面, 也同样可以为不同种类的工作头定位。
当然, 第一圆柱面 270和第二圆柱面 272也可以是轴向连续设置。 第一 圆柱面 270和第二圆柱面 272通过垂直于第一圆柱面 270和第二圆柱面 272 的台阶面连接。 不过, 由于一个圆柱面最好是适配一种最小内径的工作头。 因此, 定位元件 256的外周面 268若仅是由圆柱面形成, 那么可以根据工作 头不同的最小内径设置相应的圆柱面。
此外, 在本实施例中, 第一圆柱面 270和圆锥面 280之间以及第二圆柱 面 272和圆锥面 280之间均进行倒角处理。 如此即方便了加工, 又方便安装 工作头。
请再参见图 32 , 外周面 268与通过中心孔 265的中心线 273的纵剖面相
交形成交线。 在本实施例中, 外周面 268与通过中心线 273的纵剖面的交线 均是由三个直线段组成。 其中, 第一、 第二圆柱面 270和 272与纵剖面的交 线与中心线 273成 0度夹角, 圆锥面 280与纵剖面的交线与中心线 273成一 角度 a。 角度 a约为 50度。 当然角度 a可以根据需要设置成任意的角度。 可 以理解, 交线也可以是非直线, 如曲线或弧线其中之一, 或是直线、 曲线和 弧线几种线段的组合。
请参见图 27、 图 32和图 33所示, 第一连接孔 262a的最小内直径 dl与 第一外轮廓 274的第一最大直径 D 1相当。 将第一工作头 234a套设在第一圆 柱面 270上, 使得第一连接孔 262a正好卡设在第一圆柱面 270上, 实现第一 工作头 234a的定位。 第一连接孔 262a的最小内直径 dl 与第一最大直径 D 1 相当可以是第一连接孔 262a的最小内直径 dl 等于或略大于第一外轮廓 274 的第一最大直径 D l。 因此, 只需第一圆柱面 270与第一连接孔 262a至少部 分相接触, 就可以实现第一工作头 234a的定位。
为了使第一圆柱面 270与第一连接孔 262a的接触面足够大,且又不影响 整个多功能机的体积,第一圆柱面 270的高度与第一连接孔 262a的厚度相当。 这里,第一圆柱面 270的高度与第一连接孔 262a的厚度相当可以是第一连接 孔 262的厚度略小于或等于第一圆柱面 270的高度。可以理解,定位元件 256 还设有与第一圆柱面 270相连的底面 276 , 该底面 276 的直径大于第一最大 直径 D l。 当第一工作头 234a套设在定位元件 256上时, 底面 276会阻止第 一工作头 234a从定位元件 256上脱开。
请参见图 28、 图 32和图 34所示, 第二连接孔 262b的直径 d2与第二外 轮廓 278的第二最大直径 D2相当。将第二工作头 234b套设在第二圆柱面 272 上, 使得第二连接孔 262b 正好卡设在第二圆柱面 272 上, 实现第二工作头 234b的定位。 第二连接孔 262b的直径 d2与第二最大直径 D2相当可以是第 二连接孔 262b的最小内直径 d l等于或略大于第一外轮廓 274的第一最大直 径 D l。
优选的, 第二连接孔 262b的直径 d2与第二圆柱面 272的第二最大直径 D2相等时,第二工作头 234b的第二连接孔 262b与第二圆柱面 272配合是整 个圆周的面接触, 这样接触面更大, 定位更可靠。
为了使第二圆柱面 272与第二连接孔 262b的接触面足够大,且又不影响 整个多功能机的体积,第二圆柱面 272的高度与第二连接孔 262b的厚度相当。 这里, 第二圆柱面 272 的高度与第二连接孔 262b 的厚度相当可以是连接孔
262的厚度略小于或等于第二圆柱面 272的高度。
请参见图 29、 图 32和图 35所示, 第三连接孔 262c的最小内直径 d2与 第二外轮廓 278的第二最大直径 D2相当。 将第三工作头 234c套设在第二圆 柱面 272上, 使得第三连接孔 262c正好卡设在第二圆柱面 272上, 实现第三 工作头 234c的定位。 第三连接孔 262c的最小内直径 d2与第二最大直径 D2 相当可以是第三连接孔 262c 的最小内直径 d2 等于或略大于第二外轮廓 78 的第二最大直径 D2。 由此可见, 虽然第二工作头 234b 和第三工作头 234c 的连接孔具体形状不一样, 不过当最小内直径一样时, 与定位元件 256相接 触的外轮廓的直径则一样。
同样,第二圆柱面 272的高度与第三连接孔 262c的厚度相当可以是连接 孔 262的厚度略小于或等于第二圆柱面 272的高度。
请参见图 32所示, 圆锥面 280 包括具有第三最大直径 D 3的第三外轮廓 28 1。第四连接孔 262d的直径 d3与第三外轮廓 28 1的第三最大直径 D3相等。 如图 30、 图 32和图 36所示, 将第四工作头 234d套设在圆锥面 280上, 使 得第四连接孔 262d正好与第三外轮廓 28 1相接触, 实现第四工作头 234d的 定位。 由于第四工作头 234d是与圆锥面 280配合, 因此, 第四连接孔 262d 的直径 d3正好是与第三最大直径 D3相等, 且第四连接孔 262d与第三外轮 廓 28 1 的配合是整个圆周的线接触, 这样定位比较可靠。
如图 37所示, 在本实施例中, 配合面 282为由若干凸肋 286形成的摩擦 面。 当然, 第一实施例其它摩擦面也同样适用。
如图 33、 图 38至图 40 , 多功能机包括同第一实施例中结构大致相同的 快速夹紧机构。 在这里, 就不赘述其具体结构。 多功能机在使用第一工作头 234a时,首先将第一工作头 234a套设在定位元件 256上,使第一连接孔 262a 与第一圆柱面 270配合用于定位, 这时定位元件 256在锥簧 257的作用下抵 靠在止挡环 259上;然后将安装有第一工作头 234a的紧固件 236装到输出轴 232上; 这时操作手柄 295 , 使其围绕枢轴 292的轴线旋转, 凸轮部 294与壳 体的接触面 296相接触, 进而带动推杆 290向下移动, 使得推杆 290的凹槽 293与锁紧件 287啮合; 这时操作手柄 295 围绕输出轴 232的轴线 X沿着旋 紧的方向旋转, 从而带动锁紧件 287—起转动, 使锁紧件 287和紧固件 236 螺紋锁紧, 从而将第一工作头 234a固定在输出轴 232上。
在锁紧的过程中, 紧固件 236在锁紧件 287的配合下沿着 E方向轴向移 动, 在移动的过程中, 第一工作头 234a 的第一安装部 258 a 的上表面 283 a
贴覆在凸肋 286上, 这时继续操作手柄 295 围绕输出轴 232的轴线 X旋转, 会促使定位元件 256沿着 F方向轴向移动, 同时压缩锥簧 257 , 直到第一工 作头 234a的第一安装部 258 a的下表面 297 a贝 覆在压板 242的上表面 298上。 如此, 将第一工作头 234a固定在输出轴 232上。 最后操作手柄 295 , 使其围 绕枢轴 292的轴线旋转回复到大致与输出轴 232垂直的初始位置。
而由于凸肋 286既可以在轴向方向又可在圆周方向上在输出轴 232和第 一工作头 234a之间实现大的传力连接, 使传递的扭矩足够大, 从而保证第一 工作头 234a与输出轴 232之间不会出现相对滑动。 工作时, 输出轴 232在马 达 (未图示) 的带动下作旋转摆动, 输出轴 232输出的摆动扭矩进一步传递 给第一工作头 234a , 进而带动第一工作头 234a作摆动运动。
需要拆卸第一工作头 234a时, 只需操作手柄 295 , 带动推杆 290向下移 动, 使得推杆 290的凹槽 293与锁紧件 287啮合, 这时, 操作手柄 295 围绕 输出轴 232的轴线 X沿着旋松的方向旋转, 从而带动锁紧件 287—起转动, 直到锁紧件 287与紧固件 236完全脱开螺紋连接, 此时可将紧固件 236从输 出轴 232 中拆下, 取出第一工作头 234a。 由于第一工作头 234a的第一安装 部 258 a上的连接孔 44为封闭的, 因此, 需要将锁紧件 287与紧固件 236完 全脱离开, 以将其从输出轴 232上取下。
再参见图 40 , 第一工作头 234a的第一安装部 258 a上定义了平行与配合 面 282的第一中心面 261 a , 该第一中心面 261 a到第一安装部 258 a的上表面 283 a和下表面 297 a的距离相等。
图 41是图 40沿 C-C向的剖视图。 参见图 41 , 定位元件 256在该第一中 心面 261 a内具有第一横截面 263 a。 在这里, 第一横截面 263 a是圆环形, 其 第一外轮廓 274形成与第一工作头 234a的第一连接孔 262a相接触的第一外 接圆。 其中第一外接圆的直径为第一外轮廓 274径向尺寸 D l。
第一连接孔 262a的最小内切圆的直径为 d l , 其与第一外接圆的直径 D 1 相当, 从而实现第一工作头 234a的定位。
如图 34和图 42所示, 多功能机在使用第二工作头 234b时, 首先第二工 作头 234b套设在定位元件 256上, 使第二连接孔 262b与第二圆柱面 272配 合用于定位, 这时定位元件 256在锥簧 257的作用下抵靠在止挡环 259上; 然后将安装有第二工作头 234b的紧固件 236装到输出轴 232上;这时操作手 柄 295 , 使其围绕枢轴 292的轴线旋转, 进而带动推杆 290 向下移动, 使得 推杆 290的凹槽 293与锁紧件 287啮合; 接着操作手柄 295 围绕输出轴 232
的轴线 X沿着旋紧的方向旋转,从而带动锁紧件 287—起转动,使锁紧件 287 和紧固件 236螺紋锁紧, 从而将第二工作头 234b 固定在输出轴 232上。
在锁紧的过程中, 紧固件 236在锁紧件 287的配合下沿着 E方向轴向移 动, 在移动的过程中, 第二工作头 234b的上表面 283b贴覆在摩擦面上, 这 时继续操作手柄 295 围绕输出轴 232的轴线 X旋转, 会促使定位元件 256沿 着 F方向轴向移动, 同时压缩锥簧 257 , 直到第二工作头 234b的下表面 297b 贴覆在压板 242 的上表面 298 上。 如此, 将第二工作头 234b 固定在输出轴 232上。 最后操作手柄 295 , 使其围绕枢轴 292的轴线旋转回复到大致与输出 轴 232垂直的初始位置。
再参见图 42 , 第二工作头 234b的第二安装部 258b上定义了平行与配合 面 282的第二中心面 261 b , 该第二中心面 26 1 b到第二安装部 258b的上表面 283b和下表面 297b的距离相等。
图 43是图 42沿 D-D向的剖视图。 参见图 43 , 定位元件 256在该第二中 心面 261 b 内具有第二横截面 263b。 在这里, 第二横截面 263b是圆环形, 其 第二外轮廓 78形成与第二工作头 234b的第二连接孔 262b相接触的第二外接 圆。 其中第二外接圆的直径为第二外轮廓 78径向尺寸 D2。
第二连接孔 262b的最小内切圆的直径为 d2 , 其与第二外接圆的直径 D2 相当, 从而实现第二工作头 234b的定位。
由此可见, 第一横截面与第二横截面的形状相同, 均为圆环形, 但其外 接圆的直径不相同。 当然, 对于本领域技术人员来说, 很容易理解, 第一横 截面和第二横截面的形状也可以不相同。 比如, 第一横截面为圆形, 第二横 截面为多边形; 或第一横截面为多边形, 第二横截面为椭圆形等等。 也就是 说, 只需定位元件 256的最大外轮廓的外接圆与工作头的连接孔的最小内切 圆尺寸相当, 就可以为相应的工作头定位。 而且不管定位元件 256的横截面 是什么形状, 以及不管这些连接孔本身的形状如何。
如 35和图 44所示, 多功能机在使用第三工作头 234c时, 首先第三工作 头 234c套设在定位元件 256上, 使第三连接孔 262c与第二圆柱面 272配合 用于定位, 这时定位元件 256在锥簧 257的作用下抵靠在止挡环 259上; 然 后将安装有第三工作头 234c的紧固件 236装到输出轴 232上;这时操作手柄 295 , 使其围绕枢轴 292的轴线旋转, 进而带动推杆 290向下移动, 使得推杆 290的凹槽 293与锁紧件 287啮合; 接着操作手柄 295 围绕输出轴 232的轴 线 X沿着旋紧的方向旋转, 从而带动锁紧件 287—起转动, 使锁紧件 287和
紧固件 236螺紋锁紧, 从而将第三工作头 234c 固定在输出轴 232上。
在锁紧的过程中, 紧固件 236在锁紧件 287的配合下沿着 E方向轴向移 动, 在移动的过程中, 第三工作头 234c的上表面 283c贴覆在配合面 282上, 这时继续操作手柄 295 围绕输出轴 232的轴线 X旋转, 会促使定位元件 256 沿着 F方向轴向移动,同时压缩锥簧 257 ,直到第三工作头 234c的下表面 297 c 贴覆在压板 242 的上表面 298 上。 如此, 将第三工作头 234c 固定在输出轴 232上。
如 36和图 45所示, 多功能机在使用第四工作头 234d时, 首先第四工作 头 234d套设在定位元件 256上,使第四连接孔 62d与圆锥面 280配合用于定 位, 这时定位元件 256在锥簧 257的作用下抵靠在止挡环 259上; 然后将安 装有第四工作头 234d的紧固件 236装到输出轴 232上; 这时操作手柄 295 , 使其围绕枢轴 292的轴线旋转, 进而带动推杆 290 向下移动, 使得推杆 290 的凹槽 293与锁紧件 287啮合; 接着操作手柄 295 围绕输出轴 232的轴线 X 沿着旋紧的方向旋转, 从而带动锁紧件 287—起转动, 使锁紧件 287和紧固 件 236螺紋锁紧, 从而将第四工作头 234d固定在输出轴 232上。
在锁紧的过程中, 紧固件 236在锁紧件 287的配合下沿着 E方向轴向移 动, 在移动的过程中, 第四工作头 234d的上表面 283d贴覆在配合面 282上, 这时继续操作手柄 295 围绕输出轴 232的轴线 X旋转, 会促使定位元件 256 沿着 F 方向轴向移动, 同时压缩锥簧 257 , 直到第四工作头 234d 的下表面 297 d贴覆在压板 242的上表面 298上。 如此, 将第四工作头 234d 固定在输 出轴 232上。 如需拆卸第四工作头 234d , 由于第四连接孔 62d留有可穿过紧 固件 236的杆部 44的缺口, 则无需将紧固件 236完全从锁紧件 287上拆下, 只需拧松锁紧件 287 , 使紧固件 236与输出轴 232的之间留出可供第四工作 头 234d穿过的间隙即可。
综上所述, 定位元件 256上设有至少两个不同最大径向尺寸外轮廓与不 同种类的工作头的内径至少部分相接触, 就可以实现不同种类的工作头的定 位。 而且不管这些连接孔本身的形状如何, 由于是通过外轮廓与工作头的内 径进行接触, 从而工作头的连接孔可以是其它任意形状。 因此, 通过设置具 有不同最大径向尺寸的外轮廓的定位元件 256 , 可以使多功能机连接的不同 种类的工作头均可以快速、 准确的安装到相应的位置。
而现有技术中, 通过输出轴上的凸起和工作头的星形连接孔相匹配, 将 工作头固定安装在输出轴上。 这样, 凸起和连接孔共同起到定位功能、 固定
功能和转矩功能, 如此, 就会导致凸起和连接孔磨损的非常快。 而本发明中, 定位元件 256用于定位作用, 摩擦面与工作头的表面通过锁紧机构用于固定 功能和 /或转矩功能的。 如此, 使得定位功能与固定功能和 /或转矩功能的有 利分离。 因此, 可以减少定位元件 256、 摩擦面和工作头的连接孔等的磨损。
而且由于定位元件 256的外轮廓与连接孔的最小内径接触,只用于定位, 并未限定工作头和定位元件的相对位置。 因此, 操作者可以根据需要方便调 节工作头相对于输出轴 232的角度位置。
如图 46和图 47所示, 本发明的第六实施例与第五实施例基本相同, 所 不同的是输出轴 232上直接设置有螺紋盲孔 314 , 紧固件 316是带有螺紋的 紧固螺栓。 安装第一工作头 234a时, 首先第一工作头 234a套设在定位元件 256上, 使第一连接孔 262a与第一圆柱面 270配合用于定位, 这时定位元件 256在锥簧 257的作用下抵靠在止挡环 259上;然后将安装有第一工作头 234a 的紧固件 3 16装到输出轴 232上; 这时只需将紧固件 3 16与螺紋盲孔 314连 接, 再沿着旋紧方向旋转紧固件 316 , 就可以很轻松地将第一工作头 234a固 定在输出轴 232上。
如图 48 至图 51 , 本发明的第七实施例与第六实施例基本相同, 所不同 的是: 第六实施例中的定位元件 256进行轴向移动而适配不同的工作头; 而 在本第七实施例中的定位元件 420通过径向移动来适配不同的工作头。
如图 48 ,在实施例中, 弹性元件 422设置在紧固件 424中, 弹性元件 422 促使定位元件 420始终朝着与工作头的连接孔相接触的方向径向移动。
在本实施例中, 弹性元件是弹簧 422。 当然, 弹簧也可以是压簧或拉簧 等。
定位元件 420 包括至少两个周向设置在紧固件 424上的定位块 426 , 该 定位块 426在弹簧 422的作用下始终朝着与工作头的连接孔相接触的方向径 向移动。 当然, 在紧固件 424和定位块 426之间还设有限位装置 (未图示), 以防止定位块 426脱开紧固件 424。
在本实施例中, 定位块 426为四个,且均匀设置在紧固件 424的圆周上。 当然, 这些定位块 426也可以任意角度设置在紧固件 424的周向上。
请参见图 49 , 安装第一工作头 234a时, 首先第一工作头 234a套设在定 位元件 420上, 使第一连接孔 262a与定位块 426配合用于定位; 然后将安装 有第一工作头 234a的紧固件 424装到输出轴 232上; 这时只需将紧固件 424 与螺紋盲孔 314连接, 再沿着旋紧方向旋转紧固件 424 , 就可以很轻松地将
第一工作头 234a固定在输出轴 232上。
第一工作头 234a的第一安装部 258 a上定义了平行与配合面 282的第一 中心面 261 a , 该第一中心面 261 a到第一安装部 258a的上表面 283a和下表 面 297 a的距离相等。
图 50是图 49沿 G-G向的剖视图。 参见图 50 , 定位元件 420在该第一中 心面 261 a内具有第一横截面 428。 在这里, 第一横截面 428的形状大致为四 个分开设置的长方形, 其构成第一外接圆的直径为 D l。 在这里, 其与第一连 接孔 262a的最小内切圆的直径为 dl相当,从而实现第一工作头 234a的定位。 当然,本领域技术人员可以理解的,第一外接圆的直径 D 1与第一连接孔 262a 的最小内切圆的直径 dl相当可以是第一外接圆的直径 D l等于或略大于第一 连接孔 262a的最小内切圆的直径 dl。
图 51是沿第二工作头 234b的第二中心面 261 b的剖示图。 参见图 51 , 定位元件 420在该第二中心面 261b 内具有第二横截面 430。 在这里, 第二横 截面 430 的形状同第一横截面 428 , 其大致为四个分开设置的长方形, 但其 构成第一外接圆的直径为 D2。 在这里, 其与第二连接孔 262b的最小内切圆 的直径为 d l相当, 从而实现第二工作头 234b的定位。 在这里, 第一外接圆 的直径 D 1 与第一连接孔 262a的最小内切圆的直径 dl 相当是第一外接圆的 直径 D 1基本等于第一连接孔 262a的最小内切圆的直径 d l。
通过对比图 50和图 51 , 第一横截面 428和第二横截面 430相对于输出 轴 232的位置不相同。 由此可见, 定位元件 420通过径向移动来适配不同的 工作头。
当然, 为了可以更好的适配不同形状的连接孔, 定位块 426在与工作头 配接的一端设为圆形的尘端或圆弧端。
当然, 本实施例中定位元件 420、 紧固件 424以及弹性元件 422也可以 构成一个独立的紧固装置, 该紧固装置可以用于将多种工作头装配到一种多 功能机上。 作为一个独立的组件, 该紧固装置方便了工作头的安装。 当然, 该紧固装置也可以作为一个独立的附件出售。
本发明的第八实施例与第五、 第六、 第七实施例基本相同, 所不同的是: 前三个实施例中的定位元件进行轴向或径向移动而适配不同的工作头; 而在 本第八实施例中的定位元件通过自身的变形来适配不同的工作头。 在本实施 例中, 定位元件为变形件, 其可以设置在紧固件上, 也可以设置在输轴上。 该变形件在与第一连接孔相接触且在第一中心面内形成与第一连接孔相切的
第一外接圆; 该变形件在与第二连接孔相接触且在第二中心面内形成与第二 连接孔相切的第二外接圆。 其中根据第一连接孔和第二连接孔的最小内径不 一样, 其第一外接圆和第二外接圆的直径也不样。
当然, 本实施例中定位元件也可以同紧固件构成一个独立的紧固装置, 该紧固装置可以用于将多种工作头装配到一种多功能机上。 作为一个独立的 组件, 该紧固装置可以方便多功能机的装配。 当然, 该紧固装置也可以作为 一个独立的附件出售。
为了可以更加方便、 快速的将不同种类的工作头安装到位, 定位元件还 设有可传递扭矩的形配部。 图 52至图 62所示为本发明的第九实施例。 本发 明的第九实施例与第二实施例结构基本相同, 所不同的是定位元件的具体结 构和功能。
如图 52所示, 输出轴 532的末端设有连接法兰 558。 连接法兰 558上设 有可与工作头 534上表面相接触的配合面 560。 当工作头 534 固定在输出轴 532上时, 工作头 534的上、 下表面分别贴覆在压板 542和配合面 560之间。 在这里, 配合面 560与工作头 534上表面所产生的摩擦力足够大, 以使在多 功能机的工作过程中, 可将输出轴 532上的摆动扭矩传递到工作头 534上, 且不会使工作头 534出现打滑现象。
在本实施例中, 配合面 560是由若干规则排布的凸肋形成的摩擦面。 当 然, 第一实施例其它摩擦面也同样适用
通过输出轴 532上的配合面 560 , 使得多功能机可连接不同类型的的工 作头, 且可以将这些工作头以任意角度安装在输出轴 532上。 但是, 也带来 一些麻烦,如不能在安装时快速、准确地调整好各种工作头相对于输出轴 532 的角度。 如图 52至图 54 , 定位元件 562具有供紧固件 536穿过的中心孔 564 和转接盘 566。 在本实施例中, 中心孔 564 的横截面大致为正方形, 且与连 接部 546相匹配。 转接盘 566设有相对设置的第一端部和第二端部, 其中第 一端部面向输出轴 532且具有盘状主体 568 , 第二端部面向工作头 534。
为了更好的传递扭矩及将工作头 534以特定角度安装在输出轴 532上, 定位元件 562 包括形配部 570、 与工作头 534配接的转接部。 其中转接部至 少包括第一转接部 572和第二转接部 574 , 该第一转接部 572和第二转接部 574在垂直于输出轴 532 的平面上的投影形状不同, 从而用于连接至少两种 具有不同形状的连接孔的工作头。 而且, 两转接部的厚度均在 1 .2毫米以上, 优选 1 .2毫米, 从而可更稳固地安装对应工作头。
形配部 570由盘状主体 568的外圆周径向向外延伸而成,第一转接部 572 和第二转接部 574 自该盘状主体 568的一侧轴向凸伸而成。
形配部 570 包括至少一个从盘状主体 568的外圆周径向向外延伸的形配 元件 576。在本实施例中,形配部 570 包括四个周向均匀设置的形配元件 576 , 且每个形配元件 576 包括相对盘状主体 568 的中心具有相对平行的两侧壁 573和连接两侧壁 573的端壁 575。 优选的, 端壁 575垂直于两侧壁 573。 且 为了装配方便, 形配元件 576的两侧壁 573与盘状主体 568的外圆周通过圆 角过渡;形配元件 576的两侧壁 573与端壁 575也通过圆角过渡。输出轴 532 上设有至少部分收容定位元件 562的凹陷 577 , 在凹陷 577 的内壁形成有与 形配元件 576形状匹配的配合部。 在具体实施例中, 配合部的外轮廓与形配 部 570 的外轮廓形状相同。 配合部包括与形配元件 576相匹配的凹槽 578。 显然, 形配元件 576的外轮廓也可以是其它形状, 可以至少包括弧形或多边 形等等。
当然, 盘状主体 568的外轮廓在垂直于输出轴 532的平面上的投影为多 边形时, 如正十二边形, 形配部就直接形成于该盘状主体 568上。 如此, 在 凹陷 577的内壁也会形成与盘状主体 568的外轮廓相匹配的配合部。 显然, 盘状主体 568的外轮廓形状还可以是其它形状, 如多角形等。
在本实施例中, 定位元件 562呈阶梯状, 自盘状主体 568的表面轴向延 伸出台阶 579 , 该台阶 579为圆柱形台阶, 其径向尺寸小于盘状主体 568 的 径向尺寸。 台阶 579的厚度大于卡圏 565的厚度, 将定位元件 562安装在输 出轴 532上时, 卡圏 565位于台阶 579的圆柱面上, 且与盘状主体 568的表 面相接触。
第一转接部 572和第二转接部 574自台阶 579的端面依次轴向凸伸而成。 而且第一转接部 572最大径向尺寸可以等于或大于第二转接部 574的最大的 径向尺寸。
转接部还包括相对第一转接部 572和第二转接部 574轴向设置的第三转 接部 581。 该第三转接部 581 自第二转接部 574上轴向延伸, 其最大径向尺 寸小于第二转接部 574的最大径向尺寸。
如图 52、 图 52和图 56所示, 本实施例中, 第一转接部 572在垂直于输 出轴 532的平面上的横截面为正六边形, 且与工作头 534的连接孔 556恰好 相匹配。 工作头 534安装到定位元件 562时, 其连接孔 556套接在定位元件 562的第一转接部 572上, 并紧密配合, 从而径向定位工作头 534。 如此, 定
位元件 562可以将输出轴 532上的扭矩传递给工作头 534的同时, 还可以固 定工作头 534相对于输出轴 532的角度。 显然, 第一转接部 572的横截面还 可以是其它形状, 如与十二角形的工作头 534相匹配的十二角形等。 当然, 第一转接部 572的横截面为正六边形, 就使得工作头 534可以相对于输出轴 532有六个固定位置。
进一步地, 在本实施例中, 为了可以快速安装或拆卸工作头, 并能够提 供更强的轴向压紧力, 多功能机包括同第一实施例中结构大致相同的快速夹 紧机构。 在这里, 就不赘述其具体结构。
如图 56、 图 57所示, 多功能机在安装工作头 534时, 首先将工作头 534 套设在定位元件 562上, 使其连接孔 556套接在定位元件 562的第一转接部 572上, 并紧密配合, 从而径向定位工作头 534 ; 然后操作手柄 596 , 使其围 绕枢轴 590的轴线旋转, 凸轮部 594与壳体的接触面 598相接触, 进而带动 推杆 586向下移动, 使得推杆 586的凹槽 592与锁紧件 580啮合; 这时操作 手柄 596围绕输出轴 532的轴线 X沿着旋紧的方向旋转,从而带动锁紧件 580 一起转动, 使锁紧件 580和紧固件 536螺紋锁紧, 这时, 压缩锥簧 563 , 压 板 542轴向挤压工作头 534的安装部 552的下表面, 直到工作头 534的安装 部 552被固定在配合面 560和压板 542之间, 从而轴向固定工作头 534。 在 安装过程中, 由于第一转接部 572与连接孔 556相互匹配, 工作头 534不会 任意移动。
可以理解, 本发明中的驱动机构也不限于上述实施例中所釆用的结构。 定位元件 562的第二转接部 574和第一转接部 572形状不相同, 可连接 至少两种具有不同连接孔的工作头。 下面结合图 52至图 54 , 图 57 至图 59 具体描述本实施例中, 定位元件 562与另一工作头 600的配合情况。
如图 52至图 54所示,第二转接部 574设于第一转接部 572的轴向一侧。 第二转接部 574 包括八个自第一转接部 572轴向延伸的凸台 602。 凸台 602 自中心圆台 601径向延伸, 每个凸台 602独立且周向均匀设置。 凸台 602具 有顶面 603 , 顶面 603至第一转接部 572的顶面之间圆弧过渡。
如图 58至图 60所示, 工作头 600与工作头 534外形相似, 同样具有安 装部 604及自安装部 604弯折延伸的切割部 606 , 安装部 604上开设有连接 孔 608。 不同之处在于, 连接孔 608与工作头 534的连接孔 556形状不同。 连接孔 608为星形, 且与定位元件 562的第二转接部 574相匹配。 该连接孔
608 包括八个径向延伸的圆形凸起 610 , 相邻凸起 610 之间通过朝向连接孔 608的中心线的曲线段 612连续连接。
多功能机在安装工作头 600 时, 首先将工作头 600套设在定位元件 562 上, 使其连接孔 608套接在定位元件 562的第二转接部 574上, 也就是, 使 得圆形凸起 610与凸台 602 紧密配合, 从而径向定位工作头 600 ; 然后操作 手柄 596 , 使其围绕枢轴 590 的轴线旋转, 凸轮部 594 与壳体的接触面 598 相接触,进而带动推杆 586向下移动,使得推杆 586的凹槽 592与锁紧件 580 啮合; 这时操作手柄 596 围绕输出轴 532的轴线 X沿着旋紧的方向旋转, 从 而带动锁紧件 580—起转动, 使锁紧件 580和紧固件 536螺紋锁紧, 这时, 压缩锥簧 563 , 压板 542轴向挤压工作头 600的安装部 604的下表面, 直到 工作头 600的安装部 604被固定在配合面 560和压板 542之间, 从而轴向固 定工作头 600。 在安装过程中, 由于第二转接部 574与连接孔 608相互匹配, 工作头 534不会任意移动。
定位元件 562的第三转接部 581与第一、 第二转接部 572和 574形状均 不相同, 从而可连接其它类型的工作头。 下面结合图 60和图 61具体描述本 实施例中, 定位元件 562与另一工作头 614的配合情况。
如图 61和图 62所示, 定位元件 562的第三转接部 581 的外轮廓至少包 括圆锥面。
工作头 614与工作头 534外形相似,同样具有安装部 616及自安装部 616 弯折延伸的切割部 618 , 安装部 616上开设有连接孔 620。 不同之处在于, 连 接孔 620与工作头 534的连接孔 556形状不同。 连接孔 620为圆形, 且与第 三转接部 581 的圆锥面相匹配。
多功能机在安装工作头 614时, 首先将工作头 614套设在定位元件 562 上, 使其连接孔 620套接在定位元件 562的第三转接部 581上, 从而径向定 位工作头 600 ; 然后操作手柄 596 , 使其围绕枢轴 590 的轴线旋转, 凸轮部 594与壳体的接触面 598相接触, 进而带动推杆 586向下移动, 使得推杆 586 的凹槽 592与锁紧件 580啮合; 这时操作手柄 596 围绕输出轴 532的轴线 X 沿着旋紧的方向旋转, 从而带动锁紧件 580—起转动, 使锁紧件 580和紧固 件 536螺紋锁紧, 这时, 压缩锥簧 563 , 压板 542轴向挤压工作头 614的安 装部 616的下表面, 直到工作头 614的安装部 616被固定在配合面 560和压 板 542之间, 从而轴向固定工作头 614。
本发明的定位元件通过设置第一、 第二转接部, 甚至第三转接部, 以连 接多种类型的工作头, 从而可将输出轴 532上的扭矩进一步传递给不同类型 的工作头, 且可以快速、 准确地将这些工作头以特定角度安装在输出轴 532 上。 需要指出, 本发明的定位元件不局限于只具有第一、 第二和第三转接部, 本领域技术人员很容易想到, 可设置一个转接部或更多的安装部, 如第四、 第五安装部等等, 从而可连接更多种具有不同连接孔的工作头。 第一转接部 和第二转接部的形状也不限于上述实施例中所限定的形状, 其外轮廓还可以 是圆锥面或圆柱面等, 或第一转接部还可以是其它多边形或多角形等, 而第 二转接部凸块并不限于八个, 只要大于两个以上即可, 且凸块的具体形状也 可以是其它如圆柱等等。 当然, 第三转接部的外轮廓也不限于圆锥面, 还可 以是圆柱面或其它具有形状的凸块。
如图 63至图 65所示, 本发明的第十实施例中的定位元件 562与第九实 施例中的定位元件 562基本相同, 所不同的是定位元件 562设置的位置。 在 第十实施例中, 定位元件 562设置在压板 542上。 因此, 锥簧 563则设置在 压板 542和定位元件 562之间, 锥簧 563的弹性力促使定位元件 562始终朝 着与工作头 534相接触的方向轴向移动。在压板 542上设有止挡定位元件 562 脱开的止挡环。 在这里, 止挡环为具有开口的卡圏 622 , 在连接部 546上设 有卡槽。 卡圏 622收容于卡槽中, 防止定位元件 562脱开压板 542。
因此, 本实施例中定位元件 562也可以同紧固件 536构成一个独立的紧 固装置, 该紧固装置可以用于将多种工作头装配到一种多功能机上。 作为一 个独立的组件, 该紧固装置可以方便多功能机的装配。 当然, 该紧固装置也 可以作为一个独立的附件出售。
形配部 570 包括四个均匀设置的形配元件 576。 在第十实施例中, 压板 542上有与形配元件 576形状匹配的匹配部。 在本实施例中, 匹配部与形配 部 570 的形状相同, 为与形配元件 576相匹配的凹槽 624。 如此, 定位元件 562与压板 542形配合, 从而可以将输出轴 532上的扭矩传递给工作头 534。
下面结合图 63至图 65来具体描述本实施例中, 工作头 534与定位元件 562 中的第一转接部 572的配合情况。 至于定位元件 562其它转接部与其它 不同类型的工作对的配合情况同第九实施例, 此处就不——赘述。
多功能机在安装工作头 534时, 首先将工作头 534套设在定位元件 562 上, 使其连接孔 556套接在定位元件 562的第一转接部 572上, 并紧密配合,
从而径向定位工作头 534 ;然后操作手柄 596 ,使其围绕枢轴 590的轴线旋转, 凸轮部 594与壳体的接触面 598相接触, 进而带动推杆 586向下移动, 使得 推杆 586的凹槽 592与锁紧件 580啮合; 这时操作手柄 596 围绕输出轴 532 的轴线 X沿着旋紧的方向旋转,从而带动锁紧件 580—起转动,使锁紧件 580 和紧固件 536螺紋锁紧, 这时, 压缩锥簧 563 , 压板 542轴向挤压工作头 534 的安装部 552的下表面, 直到工作头 534的安装部 552被固定在配合面 560 和压板 542之间, 从而轴向固定工作头 534。 在安装过程中, 由于第一转接 部 572与连接孔 556相互匹配, 工作头 534不会任意移动。
如图 66所示,本发明的第十一实施例中的定位元件 562与第十实施例中 的定位元件 562 基本相同, 所不同的是输出轴 532 上直接设置有螺紋盲孔 626,紧固件 628 包括压板 630和自压板 630的中部轴向延伸的圆柱形的螺紋 部 632。 安装工作头 534时, 首先将工作头 534套设在定位元件 562上, 使 其连接孔 556套接在定位元件 562的第一转接部 572上, 并紧密配合, 从而 径向定位工作头 534 ;然后将安装有工作头 534的紧固件 628装到输出轴 532 上; 这时只需将紧固件 628的螺紋部 632与螺紋盲孔 626连接, 再沿着旋紧 方向旋转紧固件 628 , 就可以很轻松地将工作头 534 固定在配合面 560和压 板 630之间, 从而轴向固定工作头 534。 在安装过程中, 由于第一转接部 572 与连接孔 556相互匹配, 工作头 534不会任意移动。
可以理解, 同第九实施例中将定位元件 562安装在输出轴 532上, 用紧 固件 628也同样可以将工作头 534 固定在输出轴 532上。 同样, 本实施例中 仅举例说明了第一转接部 572与工作头 534的配合情况, 定位元件 562其它 转接部与其它不同类型的工作对的配合情况同第九实施例, 此处就不赘述。
Claims
1 . 一种多功能机, 可适配多种工作头, 所述多功能机包括用于安装工作头并 驱动工作头旋转摆动的输出轴、 将工作头安装在所述输出轴上的紧固件, 所述工作头具有可连接到输出轴的安装部,所述输出轴末端具有与所述工 作头的安装部配接的驱动部, 其特征在于: 所述驱动部具有与所述安装部 的表面接触的配合面, 所述配合面为摩擦面。
2. 根据权利要求 1所述的多功能机, 其特征在于: 所述多功能机还包括定位 元件和弹性元件,所述弹性元件促使所述定位元件始终朝着与工作头相接 触的方向 由向移动。
3. 根据权利要求 2所述的多功能机, 其特征在于: 所述工作头包括第一工作 头和第二工作头,所述第一工作头包括与配合面平行的第一中心面和供紧 固件穿过的第一连接孔; 所述第二工作头包括与配合面平行的第二中心 面和供紧固件穿过的第二连接孔,所述定位元件能够与第一连接孔至少部 分相接触且在所述第一中心面内具有第一横截面;所述定位元件能够与第 二连接孔至少部分相接触且在所述第二中心面内具有第二横截面,所述第 一横截面与所述第二横截面不相同。
4. 根据权利要求 3所述的多功能机, 其特征在于: 所述第一横截面的外轮廓 形成第一外接圆, 所述第二横截面的外轮廓形成第二外接圆, 其中所述第 一外接圆与所述第二外接圆的直径大小不相同。
5. 根据权利要求 3所述的多功能机, 其特征在于: 所述第一横截面的形状和 所述第二横截面的形状不相同。
6. 根据权利要求 3所述的多功能机, 其特征在于: 所述定位元件包括供紧固 件穿过的中心孔和围绕中心孔设置的外周面,所述外周面包括轴向设置的 与第一连接孔相接触的第一外轮廓和与第二连接孔相接触的第二外轮廓。
7. 根据权利要求 6所述的多功能机, 其特征在于: 所述外周面包括至少一个 圆锥面, 所述述第一外轮廓和所述第二外轮廓设于所述圆锥面上。
8. 根据权利要求 6所述的多功能机, 其特征在于: 所述外周面至少包括第一 圆柱面和第二圆柱面, 所述第一外轮廓设于所述第一圆柱面上, 所述第二 外轮廓第二圆柱面上。
9. 根据权利要求 2所述的多功能机, 其特征在于: 所述定位元件包括用于将 所述输出轴上的扭矩传递给工作头的形配部、 与工作头配接的转接部。 根据权利要求 9所述的多功能机, 其特征在于: 所述转接部至少包括与不 同形状的连接孔配接的第一转接部和第二转接部。
根据权利要求 10所述的多功能机, 其特征在于: 所述定位元件包括盘状 主体, 所述形配部由所述盘状主体的外圆周径向向外延伸而成, 所述第一 转接部和第二转接部自所述盘状主体的一侧轴向凸伸而成。
根据权利要求 11所述的多功能机, 其特征在于: 所述形配部包括至少两 个从所述盘状主体的外圆周径向向外延伸的形配元件。
根据权利要求 12所述的多功能机, 其特征在于: 所述第二转接部沿轴向 设于第一转接部的一侧, 且第一转接部与第二转接部的径向尺寸不等。 根据权利要求 10所述的多功能机, 其特征在于: 所述第一转接部和第二 转接部在垂直于输出轴的平面上的投影形状不同。
根据权利要求 10所述的多功能机, 其特征在于: 所述定位元件还包括相 对所述第一转接部和第二转接部沿轴向设置的第三转接部,所述第三转接 部的径向尺寸小于所述第一转接部或第二转接部的径向尺寸。
根据权利要求 15所述的多功能机, 其特征在于: 所述第三转接部的外轮 靡为圆雄面或圆柱面。
根据权利要求 2所述的多功能机, 其特征在于: 所述紧固件包括与工作头 接触的压板, 所述弹性元件设置在所述压板和所述定位元件之间。
根据权利要求 2所述的多功能机, 其特征在于: 所述定位元件设置在所述 输出轴内, 所述弹性元件设置在所述输出轴和所述定位元件之间。
根据权利要求 1所述的多功能机, 其特征在于: 所述多功能机包括定位元 件和弹性元件,所述弹性元件促使所述定位元件始终朝着与工作头所述第 一连接孔或第二连接孔相接触的方向径向移动。
根据权利要求 19所述的多功能机, 其特征在于: 所述工作头包括第一工 作头和第二工作头,所述第一工作头包括与配合面平行的第一中心面和供 紧固件穿过的第一连接孔; 所述第二工作头包括与配合面平行的第二中 心面和供紧固件穿过的第二连接孔,所述定位元件包括至少两个周向设置 的定位块,所述至少两个定位块与第一连接孔相接触且在所述第一中心面 上定义了第一横截面;所述至少两个定位块与第二连接孔相接触且在所述 第二中心面定义了第二横截面,所述第一横截面和所述第二横截面相对于 所述输出轴的位置不相同。
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CN201210014641.3A CN103101039B (zh) | 2011-11-11 | 2012-01-18 | 紧固装置和可应用该紧固装置的多功能机 |
CN201210014641.3 | 2012-01-18 | ||
CN201210061584.4A CN103302640B (zh) | 2012-03-09 | 2012-03-09 | 多功能机 |
CN201210061584.4 | 2012-03-09 |
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US10137592B2 (en) | 2013-05-06 | 2018-11-27 | Milwaukee Electric Tool Corporation | Oscillating multi-tool system |
US10940605B2 (en) | 2013-05-06 | 2021-03-09 | Milwaukee Electric Tool Corporation | Oscillating multi-tool system |
US11724413B2 (en) | 2013-05-06 | 2023-08-15 | Milwaukee Electric Tool Corporation | Oscillating multi-tool system |
CN104339034A (zh) * | 2013-07-30 | 2015-02-11 | 苏州宝时得电动工具有限公司 | 锯片及摆动机 |
US20180311746A1 (en) * | 2013-08-01 | 2018-11-01 | C. & E. Fein Gmbh | Power tool |
US10471518B2 (en) | 2013-08-01 | 2019-11-12 | C. & E. Fein Gmbh | Machine tool with tool-accommodating device |
US10807170B2 (en) | 2013-08-01 | 2020-10-20 | C. & E. Fein Gmbh | Tool device |
US10967435B2 (en) * | 2013-08-01 | 2021-04-06 | C. & E. Fein Gmbh | Power tool |
US11590584B2 (en) | 2013-08-01 | 2023-02-28 | C. & E. Fein Gmbh | Tool device |
CN113352476A (zh) * | 2021-05-28 | 2021-09-07 | 福建巨邦机械有限公司 | 一种便于安装的机架及大切机 |
CN113352476B (zh) * | 2021-05-28 | 2023-02-14 | 福建巨邦机械有限公司 | 一种便于安装的机架及大切机 |
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US20140290072A1 (en) | 2014-10-02 |
US10946544B2 (en) | 2021-03-16 |
US20190118402A1 (en) | 2019-04-25 |
EP2762276A4 (en) | 2015-05-20 |
EP3090839A1 (en) | 2016-11-09 |
EP2762276B1 (en) | 2016-07-27 |
EP2762276A1 (en) | 2014-08-06 |
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