SE464662B - Operating lever - Google Patents

Abstract

Operating lever with an operating head 1 and an elongate lever part 2. At one end, this lever part bears the operating head and, at a distance from this end, it is connected to a mechanism which is to be operated. The operating head has an electric switch 14, 12. The operating head 1 is somewhat movable in the radial direction relative to the longitudinal axis 3 of the lever part and has a cavity 4 into which the lever part 2 projects with one 10 of its ends. The cavity 4 has a peripheral surface 11 which has an interspace to the surface 12 of said end of the lever part. Located in the interspace are on the one hand an elastic, annular centring element 13 which bears with its outer periphery against said peripheral surface of the cavity and with its inner periphery against the surface 12 of the lever part, and on the other hand an annular electric contact element 14 which forms part of the switch and is securely connected to the operating head and adapted to follow its radial movements. The centring element 13 tends to centre the contact element relative to the end portion 10 of the lever part. In a neutral position of the operating head, the movable contact element has an interspace to the end portion of the lever part (the end portion forms a second contact element in the switch). When the operating head is manually moved laterally relative to the lever part, the annular contact element is displaced into an eccentric position in contact with the second contact element. <IMAGE>

Description

464 662 2 Fig. 4 is a radial section through the device along the line . Iv-Iv in Fig. 1, Fig. 5 is a section, corresponding to that of Fig. 2, but with the device in an activation position, Fig. 6 is a section corresponding to the section in Fig. 1 the control lever in a second embodiment, Fig. 7 is a section along the line VII-VII in Fig. 6, m Fig. Is a section corresponding to the section in Fig. 6 the control lever in a third embodiment, and Fig. 9 is a section along the line IX-IX in Fig. 8.

The control lever according to the invention is intended to be in one and the same lever movement to effect both a mechanical adjustment of a mechanism as an electrical activation of a device such as either forms part of said mechanism or is completely separate from this. The control lever in the examples shown is special suitable for use as a gear lever for conversion between different gear positions by manual operation. The control lever is, as shown in Fig. 1, mainly built up of an operating housing vud 1, commonly referred to as lever knob, and a substantially long stretched lever part 2, of which only its upper_part is shown the drawings. The lever part 2 carries at its upper end the operating head 1 and is connected at its lower end to the mechanism to be be maneuvered or forward the maneuvering movement, which is a oscillating movement, so that the movement of the operating head in the main thing takes place laterally, ie transversely to the longitudinal axis 3 of the lever part.

The lever part 2 consists of a cylindrical tube, which inserts in a downwardly open cavity 4 of the actuating head 1. On the lever part is threaded a bushing 5 made in an electrically insulated learning material, for example relatively shape-resistant * plastic.

The bushing has a through hole with an inwardly facing cyanide. lightweight mantle surface 6, which with a good fit connects to a corresponding outwardly facing cylindrical circumferential surface 7 of a portion of lever part 2 so that the bushing is firmly connected to it. This lot 7 passes via a ledge 8 to the lever part below level mantle surface, which has a larger radius of curvature. Thereby a stop stop is obtained for the bushing 5, which thus cannot shifted further downwards. The bushing is so located, that 3 above the bushing, an end portion 10 of the lever part projects, which in the example shown shows a further reduced radius relative to the portion 7 of the lever surface of the lever member. The end party 10 inserts into an inner cylindrical portion of said cavity 4 in the operating head 1 with an inverted cylindrical outer surface 11, which has an annular space to the outside of the end portion 10 facing mantle surface 12. In said space an elastic is inserted centering element 13 of a highly elastic material, such as silicone in the form of an o-ring, which with its inner periphery abuts against the mantle surface 12 of the end portion 10 of the lever member and with its exterior periphery abuts against the cylindrical mantle surface 11 in the upper head 1.

In the cavity of the operating head 1, more precisely in the same cylindrical portion as the centering ring 13, is located an annular electrical contact element 14, made in an electric oath materials, such as metal. This contact element 14 is included; i en i the control lever, more precisely: in the control head J. included electric switch, where the annular contact element 14 represents a movable contact element, while the end portion , more precisely, its cylindrical mantle surface 12 forms the second, fixed contact element of the switch, where the lever part 2 unit connection forms the connection conductor to the fixed contact in that the lever part is electrically conductive or at least made with an electrically conductive;: ikt, whereby a connection cable to one through the switch terminable circuit can be connected anywhere, preferably below the operating head 1.

A suitably insulated connection conductor 15 is shown in Fig. 1 and is connected at one end to the movable contact element 1 = and with its other end to an electrical circuit for an electrician. nanover function. Example of such a control function constitutes electrical operation of a clutch, whereby manual coupling to a motor vehicle can be eliminated while maintaining of a traditional manual transmission. The movable contact More specifically, the element 14 is fixedly attached to its outer periphery 16 in the inwardly facing mantle surface 11 and thus has i 464 6621 464 662 essentially the same diameter as this to with good fit be able to be firmly attached to the operating head 1. 4 In the first example of the control lever shown in Figs. 1-5 the movable contact element 14 consists of a single, unbroken one electrically conductive ring in the shape of a simple screw washer. The the inner periphery 17 of the annular contact member 14, as well as its outer periphery is cylindrical shell-shaped or at least shows a circular contour line, but shows a clearly larger one diameter than the diameter of the mantle surface of the end portion of the lever portion , see Fig. 2. In the neutral position shown in Figs. 1 and 2 for the operating head 1 in relation to the operating lever and thus a neutral position of the switch is the movable contact element 14 coaxially with the fixed contact element 10, i.e. the end portion of the lever portion 2. In the neutral position is thereby present an annular contact extending around the end portion space 18, which in the first embodiment has a and the same width all around, ie is rotationally symmetrical. Power switch reindeer is thus open. This contact gap 18 shall be large enough that contact in this neutral position does not shall be present and that vibrations in the control lever shall not either shall cause unintentional contact between the contact parts in the switch, but should still be as small as possible for to result in a fast and early contact function at the movements, which can be seen in more detail below.

The operating head 1 is well centered in its neutral position and controlled in relation to the lever part 2, but still slightly movable guided, i.e. across the longitudinal axis 3 of the lever part and thus substantially in the radial direction through the connection of the control lever to the lever part via the centering element 13 and the bushing 5. Furthermore the operating head a central shaft 19 with a hinge ball 20 in its lower end, the shaft and the ball joint projecting into the lever part 2 cylindrical elongate cavities 21. The articulation ball 20 has one such diameter and such fit in the cylindrical cavity 21 that the ball joint 20 allows a small oscillating movement of shaft 19 with the joint ball 20 as the joint center, at the same time as this has a certain retaining effect for the operating head 1 through 464 662 friction against the inwardly facing casing wall of the lever part in the cavity 21.

The shaft has an enlarged portion 22 at the top with a mantle surface 23, which maintains an annular gap 24 whose radial distance slightly exceeds the radial distance in the contact gap 18.

Furthermore, the inwardly facing circumferential surface 11 of the operating head passes one piece below the movable contact element 14 in a downward direction facing, slightly inclined ledge surface 25, showing such an angle that it coincides with the main direction of an arc of a circle with the ball joint 20 center as the center of curvature. An equivalent upwardly facing ledge-like support surface is formed in the bushing 5 and these two ledge surfaces 25, 26 form sliding surfaces and support surfaces so that the operating head 1 here receives a stop stop against the bushing 5 and the desired small lateral, radial movement of the actuating head. In this way, maintenance a gap 27 is read between the upwardly facing end surface of the lever part and a downward-facing surface of the cavity in the lever head, whereby the friction during the movement of the lever head relative to the lever part is maintained despite the load of the operator on the control body 1 with his hand.

Figures 3 and 4 show the special design of the bushing for to form a snap lock by means of two snap means 28 for axially holding the operating head 1 against lifting from the lever part 2 and partly by means of a recess 29 form a rotary lock for the operating head 1 so that it cannot be freely rotated around the lever part 2. For the primary functions of the control lever, the control head in and per se rotation is allowed, but from experience one is achieved better maneuverability if the head is torsionally stable. Furthermore, the upper head at the top have symbols for, for example, gear gene, which should assume a predetermined angular position. The snap organs 28 are elastically resiliently radially inwardly, which enables a simple mounting of the operating head 1 by this is simply applied to the end portion 10 of the lever portion 2, wherein the snap means 28 by co-operation with inserting hook forks miga portions 30 of the actuating head are removed and spring back by cooperating with stop stops 31 on the hook-shaped 464 662 6 the parts prevent lifting of the control head 1. The rotary lock is achieved by the operating head 1 being formed with a radially projecting means 32, which has abutment surfaces 33 which are so located that they ensure 'practically rotary locking by co-operation with corresponding surfaces in the recess 29, whereby on the other hand radial movements of the operating head are allowed with low friction.

An additional operating possibility exists with that in the figures shown design, namely by means of an axially movable operating sleeve 34, which is arranged to be displaced with the lever part 2 as control by gripping it between two of the fingers of the hand and is lifted into an upper end position during operation of the the upper lever with the control head 1. This control sleeve 34 is used jas usually to expose a latch against unintentional loading of reverse gear. The control sleeve 34 is normally held in a lower position end position, shown in Fig. 1, by means of a spring (not shown). The the lower breathing position is formed by a projection 35 arranged in the bushing which is brought into abutment against a stop surface 36 in a recess 37 in the operating sleeve 34. However, it is possible to upward sliding of the control sleeve to provide the radial displacement the sliding of the operating head 1 to switch the switch in the operating head to the closed position. This is accomplished by that the actuating sleeve has an inclined guide surface 37, which through interaction with a corresponding inclined guide surface 38 in the operating the head causes this radial displacement.

Function of the control lever with regard to activation of current the stall should be apparent from the above description of the structure of the control lever. However, the function herewith summarized. Adjustment of the control lever always takes place by means of actuation of the operating head 1, which is gripped by the operator's hand and page shifted to a selected activation mode, e.g. one gear position. However, the lever part 2 is fixed in a mechanism, which offers a resistance that exceeds the resistance ring ring 13 offers the operating head in its endeavor to center the operating head relative to the lever part 2. In the one shown in Fig. 1- 4, the operating head thus has a centered one 7 neutral position and in the case of a radially directed hand movement on the lever head 1 in any direction, the centering element is compressed element 13 on the side of which the force is applied, whereby the it is allowed to move sideways to an eccentric position relative to the lever part 2 and more precisely its longitudinal axis 3. Already in the event of a very small displacement, contact occurs somewhere between the contact means movable by the movement of the operating head element 14 and the fixed contact element, i.e. the end of the lever part lot 10 and more specifically its mantle surface. Such an action mode is shown with an example in Fig. 5, taken after that the operating head 1 has been moved, viewed in the section according to Fig. 5, in the direction obliquely upwards to the right. This results in closure of the switch and to this connected circuit, which in the present case entails disengagement of a coupling mechanism, before switching.

As soon as the grip on the operating head 1 ceases, it resets 'to its centered position through the centering ring 13 striving to regain its original form and thus exercise one force action against the jacket wall 11, within which the centering the ring 13 is located, the contact element_14 being centered again and the contact gap 18 is maintained all around, the current the stand is opened and the switching function is switched on, when the stock position has been taken. By both the centering ring 13 and the contact ring 14 are located in the same space between the parts the end portion of the lever part 2 and the inwardly facing part of the operating head mantle surface 11 is ensured that the contact ring 14 is at all times 464 662 ' centered regardless of any deviations due to tolerances during manufacture. It is obvious that those around the contact the parts located in addition to the contact elements themselves are off electrically insulating material so that it does not close stream. is another way. The operating head is made in one relation needle-resistant, shape-resistant, but grip-friendly material, which may be slightly deformable in its surface, while the bushing 5 can be made of a slightly harder material, such as hard plastic. The control sleeve 34 can also be made of a plastic material. -464 662 8 The control lever according to the second embodiment, shown in Fig. 6 and 7, corresponds to the first embodiment of except for the structure of the movable contact element. This contact elements, denoted here by 40, also consist of one mainly annular element, but does not consist of a closed one ring, but is divided into two or more, in the example shown four electrically conductive sections 41-144, which here are electrically isolated from each other by being spaced apart 63 between each other and by means of each individual electric connection can be included in a separate circuit for each contact element section. Through the smaller of the fixed contact element 10 outer diameter of the mantle surface, which also in this example constitutes its contact surface, becomes the contact steel during the movement of the operating head 1 to an eccentric position, also in this case a point contact, viewed in the section according to Fig. 7, whereby in principle contact obtained with only one contact sector at a time. This causes so that a predetermined circuit is closed depending on the direction of the radial movement to the eccentric position of the operating head 1. With this division of the movable contact the element is thus obtained a multi-position switch with one the contact part is common and connectable to _one of several contact parts. Thereby thus can different electrical functions is switched on depending on the direction of movement of the operating head. At the application as a gear lever can be, for example, an electrically driven clutch mechanism is activated with varying time delay in depending on which gear is to be engaged, ie in which direction the actuating head is brought and thus which contact activated.

The sectional contact element 40 according to Figs. 6 and 7 is in principle attached in the same way as the contact element according to the first embodiment, i.e. the position of an inwardly facing i mainly rotationally symmetrical surface, which constantly has a solid reference to the inwardly facing rotationally symmetrical surface which positions the centering element 13, i.e. in the examples shown the inwardly facing cylindrical surface 11, which is the common position control surface for both the centering element 13 and the contact element 40. In the embodiment of Figs. 6 and 7, the contact 9 464 662 ' the element 40 is further provided with an annular holder 45 of an electrically insulating material in which the contact sections 41, 42 are partially baked so that their inner periphery 47, i.e. their circular arcuate contact surface, can be brought in electric contact with the contact surface 48 of the second contact element 10, which consists of the mantle surface of the upper part of the lever part. Further is the holder 45 is rotatably mounted in the operating head 1 so that the contact the sections maintain predetermined angular range around the longitudinal axis of the control lever 3. In this second embodiment it is cylindrical guide surface 11 provided with a recess 49, in which the holder 45 inserts with a corresponding projection 50. At operation by means of the control lever according to Figs. 6 and 7 from its neutral position, the contact section 41-44 is closed as through the radial movement of the operating head to the eccentric position is carried towards the fixed contact part. In this example is divided the contact functions in four equal angle sectors of approx 90 ", the sector boundaries being determined by the gaps 63 modes.

The third embodiment of the control lever, shown in FIG. 8 and 9, constitute an alternative to the second embodiment according to Figs. 6 and 7, but gives the same principal electrical function like this, namely closing of various electrical circuits depending on the direction of the maneuvering motion of control lever. In the third embodiment, only two contact modes for a closed switch, but also this one solution can be adapted to the wishes of several contacts. functions. In the third embodiment, one has instead a division of the periphery of the annular contact element chosen to divide the contact element into element sections that are located at different levels along the top part of the lever part 2. One can say that the contact element is sectioned into sections that lie in different radial plane around said upper portion, which represents the solid the contact element. In practice, it is mobile, annular the contact element supplemented with an additional movable, annular contact element for each contact position desired. IN the example shown, two contact positions are desired, where the switch is closed, so two contact elements 51, 52 represent it 464 662 10 together with the actuating head 1 the moving part of the switch clean. In order to, like the embodiment according to Figs. 6 and 7 achieve a sectoral division of the effective contact area of the movable contact elements 51, 52, these are thus placed on different levels along the upper part of the lever part and also made with radially slightly offset inner peripheries 53, 54, ie have mutually offset centers of curvature whereby the inner peripheries only over a part of their circumference constitutes the switch's active contact surface. In what was shown In the example, the contact elements 51, 52 have been designed so that their outer peripheries 55, 56 are concentric and similar the examples according to the above are held by the inwardly facing cylindrical the guide surface 11 in nmn fi at all 1. Between this guide surface and the end portion 10 of the lever part 2 is the elastic centering element 13 located and vertically located between the switches of the switch contact element 51 and the end face of the rotationally symmetrical cavities which are bounded, inter alia, by the guide surface 11. The difference in centrici- the accuracy of the two contact elements 51, 52 is achieved in this example simply because these are designed with their own circular holes, which are offset from each other in terms of their curvature. center. To maintain a substantially symmetrical contact gap 57 in the neutral position shown in Fig. 9 with open switch is in the example shown the two contacts elements 51, 52 symmetrically eccentric relative to the operating head. its 1 and the joint longitudinal axis 58 of the lever part 2, wherein centers of curvature of the two inner peripheries 53, 54 with advantage are diametrically opposite located on either side of said longitudinal axis 58 and located at an equal distance from it. In order to ensure the predetermined angular range of the contact function The contact elements 51, 52 are locked in the selected rotation position relative to the longitudinal axis 58. This is solved in the example shown in that they are provided with a projection 59, which projects into a corresponding recess 60 in the operating head 1.

As will be appreciated from Figures 8 and 9, the eccentricity of the contact the inner peripheries 53, 54 of the element 51, 52 to cause over a certain angular range, in the example shown 180 °, closer determined to the right of the line of symmetry 61 one contact element 11 464 662 51, in the example shown the upper contact element, that protrude and be closer to the fixed contact element contact surface, i.e. its periphery 62. Since the two inner peripherals lines 53, 54 are circular and correspondingly lower the contact element to project and be with its inner periphery located closer to the fixed contact element than the upper contact element. the inner periphery of the telement over the other 180 'of the total the periphery, more precisely to the left of the line of symmetry 61.

When operating by means of the control lever according to Figs. 8 and 9 from in the neutral position and in one direction the angular range is 180 ° to to the right of the line of symmetry 61, the wan head 1 will radially shift so that contact between the fixed contact element and the lower contact member 52 is reached over the left one half of its inner periphery, with the switch and supply associated electrical circuit is closed for conversion of a electrically driven device, activation of an indicating means etc.

The invention is not limited to the above-described and embodiments, but can be varied on one several ways within the scope of the appended claims. Example- it is conceivable that the centering element 13 is located between the upper part 22 of the shaft and the inner wall of the lever part 2.

In this case, the contact ring 14 itself can be kept out, but can also alternatively be placed around the shaft 19 upper end, the inwardly facing circumferential surface surface 21 of the lever part 2 forming contact surface for co-operation the movable contact element 14. I instead of_excentrically displacing the interior of the contact elements periphery as shown in Figs. 8 and 9, the contact elements alternately given different radii of curvature across different sectors of their inner periphery. The term "fixed contact element" means that in the switch is this element fixedly arranged in the control lever, while the "movable contact element" is movable together with the operating head. By "contact surface" is meant the surface of the respective contact element, over which contact can be obtained between it movable and the fixed contact element, taking into account the the structure of the switch.

Claims (15)

464 662 12 Patent claims Actuating lever with an actuating head (1) and an elongate lever part (2) which at its one end supports the actuating head and is at a distance from said end connected to a mechanism to be actuated, the actuating head having an electric switch (14,12 / 40,48 / 51,52,62), characterized in that the operating head (1) is slightly movable in different directions in radial direction relative to the longitudinal axis (3) of the lever part and has a cavity (4) into which the lever part ( 2) inserts with its one end portion (10) and that said cavity (4) has a peripheral surface (11) which has a gap to the mantle surface (12/48/62) of said end portion of the lever part, that in said gap is located partly an elastic, annular centering element (13) which with its one periphery abuts against said peripheral surface of the cavity and with its other periphery abuts against said end portion of the lever part and_h partly at least one annular, movable electrical contact element (14 /) included in the switch 40 / 51.52) which is connected to the operating head and arranged to follow in its radial movements, that said centering element (13) strives to center said contact element relative to said end portion (10) of the lever part so that in a neutral position of the operating head the movable the contact element has a gap to said end portion of the lever part, which end portion forms a contact element fixed in the operating lever, included in the switch, and that in a manual lateral movement of the operating head relative to the lever part in any of said different directions, the annular contact element is displaced radially led to one of several different contact positions in contact with the other contact element. Actuating lever according to claim 1, characterized in that said annular contact element (14) has an unbroken contact surface (17) in the form of a closed periphery extending around said end portion (10) of the lever part (2). and is arranged to stop a predetermined electrical circuit when operating by means of the control lever, independent of the selected contact position. Actuating lever according to claim 1, characterized in that said movable contact element (40/51, 52) is arranged to be brought into contact with the fixed contact element (10) in sections, whereby different contact functions are obtained in different directions. Control lever according to Claim 3, characterized in that the movable contact element (40) is divided so that it consists of two or more electrically insulated sections (41-44), each with its own contact surface, which occupies a predetermined sector around the longitudinal axis of the control levers (3). Actuating lever according to claim 3, characterized in that the movable contact element is divided so that it consists of two or more closed ring elements (51, 52) extending around the fixed contact element (10), wherein the contact surface for each of the ring elements extends over one or more predetermined sectors around the longitudinal axis of the control lever (3). Actuating lever according to claim 5, characterized in that the contact surface of each of the ring elements (51, 52) is formed by a portion of their inner periphery (53, 54) and that the inner peripheries of the ring elements are formed by circular arc lines with offset bending centers. Actuating lever according to claim 1, characterized in that said peripheral surface (11) of the cavity (4) is constituted by an inwardly facing casing surface, which forms a support surface for both the centering element (13) and the annular contact element (14 ). Actuating lever according to claim 1, characterized in that the lever part (2) is tubular and encloses a central shaft (19) with the operating head unconnected with an operating head (20) arranged to form a guide center for the radial movement of the operating head. . Actuating lever according to Claim 1, characterized in that an axially displaceable bushing (5), made of an electrically insulating material, is arranged on the lever part (2) and enclosed in the cavity (4) of the operating head (1) and has support and sliding surfaces (26) which extend transversely to the longitudinal axis (3) of the lever part (2) and on which the operating head is supported by corresponding support and sliding surfaces (25) on the operating head so that a gap (27) is maintained between the end surface of the lever part the cavity (4) and surfaces facing the end surface in the cavity. Actuating lever according to Claim 9, characterized in that the actuating head (1) and the bushing (S) are provided with snap means (28, 30) which form a snap lock arranged in a mounting torque for mounting the actuating head. (1) allow axial threading of the operating head on the lever part (2) to abutments between said support and sliding surfaces (25, 26) but to lock against axial movements of the operating head in the opposite axial direction. Actuating lever according to claim 1, provided with an axially movable actuating sleeve (34), which is arranged to be displaced along the lever part (2), characterized in that the actuating sleeve (34) has guide means (37) for co-operation with guide means (38) in the actuating head (1), arranged to cause said radial movement of the actuating head in the case of axial displacement of the actuating sleeve. Control lever according to one of the preceding claims, characterized in that the control lever consists of a gear lever for switching between different gear positions of a gearbox in a motor vehicle and that said switch (12, 14) is arranged to switch on an electrically driven clutch. nordning for release during the shifting moments. f! 15 464 62 A male lever according to claim 12, characterized in that said operating sleeve (34) is included in a locking mechanism, arranged to be released manually when adjusting a reverse gear, wherein the coupling device is disengaged. Actuating lever according to claim 1, characterized in that the operating head (1) is non-rotatably connected to the lever part (2), i.e. locked against rotational movements about its longitudinal axis (s). Actuating lever according to claims 9 and 14, characterized in that the bushing (5) is rotatably mounted on the lever part (2) and has locking means (29) arranged to be in engagement with corresponding locking means (32) in the operating head (1) for rotating this relative to the lever part.