DE19828127A1 - Rotation signal source for precision or measuring device e.g. setting control for car radio - Google Patents

Abstract

The rotation signal source provides an electrical signal in response to rotary movement of a spline (1) fitted with a rotary knob (2) via interlocking projections of one of the latter fitting into corresponding recesses in the other. The rotary knob is provided as a compound component with a hard spring core (3) receiving the spline and a soft elastic mantle (4) around the outside of the core.- DETAILED DESCRIPTION - An INDEPENDENT CLAIM for a rotary knob for a rotation signal source is also included

Description

There are rotary encoders for the transmission of rotary movements in electrical signals known a cylindrical pivot pin on which a knob by means of a Grub screw is fixed against rotation. The rotary movement of the rotary knob is controlled by the Transfer grub screw to the cylindrical pivot pin, creating different electrical circuits in the circuit arrangement of the encoder opened or closed become. Such encoders are used in a variety of ways in the electronics industry. This Encoders prove to be very complex to assemble because each rotary knob must be placed individually on the cylindrical pivot pin and the grub screw must be fixed individually in the rotary knob by turning with a screwdriver. This requires a very precise handling of the screwdriver when inserting it into the Grub screw and then tightening it. So far clearly that this process is difficult to automate.

The invention has for its object to provide an encoder that one machine manufacturing is particularly accessible and where the rotary knob is fixed on the knurl as securely as possible.

This object is achieved by a rotary encoder for the transmission of Rotational movements in electrical signals with the features of claim 1 solved.

Advantageous further developments result from the subclaims.

According to the invention, the rotary encoder is used to transmit rotary movements in provide electrical signals with a knurl and a rotary knob. The sits Turn the knob positively on the knurl. The positive connection of the Knurling with the rotary knob is done by one or more elevations on the knurling or the rotary knob and by one or more correlating to the elevations  Recesses are formed on the rotary knob or the knurl. Furthermore, the rotary knob a composite piece from a hard and resilient core for receiving the knurl and a soft and elastic coat that encompasses the core. The coat engages around the core in such a way that the core is pressed together and thereby a secure positive connection between the core of the rotary knob and the knurl given is.

In addition, the soft, elastic jacket of the knob ensures that the user of the encoder turns the knob in a comfortable way can safely grasp what, especially with precision devices or measuring devices from is of particular interest.

In addition, the use of the soft and elastic jacket proves itself Particularly advantageous for an application in the automotive sector, because Injuries when impacting such a knob, for example in the Use of a rotary encoder according to the invention in a car radio in the dashboard, considerably reduced by the flexible, soft and elastic structure of the jacket are.

The core preferably has one or more slots which are resilient Ensure enlarging the recess to accommodate the knurl. Through this Slits, which are preferably the cylindrical recess in the core for receiving the Cut the knurl so that the axis of rotation of the cylindrical recess is part the slits is. This arrangement of the slots ensures that a Insert the knurl into the corresponding recess with a slightly larger one Outside diameter than the inside diameter of the recess to a certain extent Spreading the core leads and the knurl through the resilient design of the core is tightly enclosed. This ensures that the core is securely fixed to the knurl guaranteed, which is additionally reinforced by the jacket surrounding the core becomes. The jacket preferably encloses the core apart from that Knurled side of the core completely. This is achieved according to the invention that only the jacket of the encoder in the in one electronic device, for example, a car radio installed state can be seen and not part of the core is accessible to the user, one relative to the shell poor tactile properties and one due to its relatively high hardness  shows limited traffic safety. Due to the special resilient training of Kerns by means of the slots can also be easily machined implement, as it is not a matter of fixing the respective knob on the knurl the manual operation of a grub screw arrives but only on putting on the Knob with the core on the knurl and its resilient and positive Connection.

According to a preferred embodiment of the rotary encoder according to the invention Knurling cylindrical and longitudinal on its outer surface Elevations arranged together with the recess in the core for receiving the Knurling ensure a press fit. This is particularly true then advantageously achieved when the knurl is made of a harder material than the core for example made of steel and the inner diameter of the recess in the core Recording the knurl has a smaller diameter than the outer diameter of the cylindrical knurl with its longitudinal elevations. In this case the hard and longitudinal elevations of the knurl intersect when Applying the knob with the core in the hard but relative to that Knurls softer core of the knob and thereby form the to the elevations correlating recesses at the core. This is a non-rotating and given positive connection of the knurl with the rotary knob. Such Formation of the knurl and the core enables the machine to a particular extent Connect the rotary knob to the rest of the encoder as it is not on one specific orientation of the rotary knob arrives relative to the knurl. It is about a rotationally symmetrical design of the core with the jacket and the Knurl. In addition to the mechanical application of the rotary knob to the knurl, it is also possible to machine the rotary knob again very easily if required decrease as this can be done by simply pulling the rotary knob in the longitudinal direction of the cylindrical knurl can be achieved.

According to a preferred embodiment of the encoder, the knurl or Core in the area of the recess for receiving the knurl with a ring circumferential groove. A groove which engages in the annular circumference engages in this groove correlating elevation in the counterpart, i.e. either in the area of the recess Take up the knurl in the core or on the knurl. This survey takes effect in Art  a tongue-and-groove connection into the ring-shaped circumferential groove and sets sure that the knob of the knurl is both simple and therefore can be applied mechanically or removed, with the locking Tongue-and-groove connection between core and knurl an unwanted falling off of the Knurled knob even under extreme conditions such as one automotive application for off-road driving over gravel and scree roads is prevented. Especially through the interaction of the hard, resilient core The knurl is picked up with one or more slits and the soft, elastic one Sheath as well as the annular circumferential groove and the elevation is a very safe locking connection between the knurl and rotary knob ensured by the appropriate design of the size of the slots, the choice of material for the core or the jacket or its dimensions including the dimensions of the annular recess or the elevation can be the required force Control overcoming the locking effect very precisely in different ways and the Adapt the requirements of the respective area of application.

The locking connection can be through one or more elevations in the form of noses be formed. These training courses are related to the ring-shaped Formation of the recess ensures that the rotary knob in any rotational position can be placed on the knurl, because the survey or surveys engage regardless of their rotational position at any point of the annular recess can. In a preferred embodiment, a single elevation is formed which has an annular shape from the annular recess in the assembled state of the encoder is completely recorded. By on the one hand, this ring-shaped formation of the elevation is for one machine handling important rotationally symmetrical freedom of attachment guaranteed and on the other hand a clear force for overcoming the Given locking action, which means the secure mounting of the rotary knob on the knurl guaranteed particularly advantageous manner.

The jacket of the rotary knob for the rotary encoder is preferably made of an elastic one Made of plastic that has a hardness of less than 50 Shore. With this choice the plastic hardness manages to be very pleasant in a particularly advantageous manner to achieve tactile sensation when operating the rotary encoder and on the other  especially in an automotive application and in particular in the area of Dashboards produce a particularly injury-proof encoder. Through this Training of the encoder are injuries in the event of an impact on a body part the hardness of the encoder is significantly less important due to a traffic accident.

It has proven to be most suitable to manufacture the core as an injection molded part and on this injection molded part in turn the jacket made of a soft, elastic material spray on. This type of production is very economical Manufacturing ensures what is particularly important for an application in the automotive sector is of particular importance. In addition, this type of molding shows a very suitable way to achieve a firm connection between the shell and core, the in particular no or almost no air bubbles or the like in the area of their Connection surfaces shows what the power transmission from the jacket to the core on very ensures precise, long-lasting manner. This also makes it safe to enclose and thereby the resilient, elastic compression of the core by the jacket guaranteed particularly suitable manner. Thus, the invention Functionality through this constructive design of the rotary knob as a plastic Composite injection molded part particularly suitable for a rotary encoder.

The invention also relates to a rotary knob for use in a rotary encoder Knurl. The knob is a composite piece made of a hard and resilient Core for receiving the knurl and a soft and elastic coat that the Grips around, trained. The jacket surrounds the core in such a way that the core is pressed together and thereby a secure positive connection between the core of the rotary knob and the knurl. In addition, the soft, elastic jacket of the knob ensures that the user of the Rotary knob for the encoder can safely take what is of particular interest, particularly in the case of precision devices or measuring devices. In addition, the use of the soft and elastic jacket proves itself Particularly advantageous for an application in the automotive sector, because Injuries when impacting such a knob, for example in the Use of a rotary encoder according to the invention in a car radio in the dashboard, considerably reduced by the flexible, soft and elastic structure of the jacket are.  

A preferred embodiment of the invention is shown in FIGS. 1 and 2 and is described in more detail below.

Fig. 1 shows a longitudinal section through an encoder according to the invention. The rotary encoder is composed of the rotary knob 2 and the knurl 1 , which is followed by an electrical circuit arrangement which generates the electrical signals on the basis of the rotary movement transmitted by the rotary knob 2 via the knurl 1 .

The rotary knob is composed of the hard, resilient core 3 and the soft, elastic jacket 4 as a composite workpiece. The jacket 4 encompasses the core 3 from all sides except for the side facing the knurl 1 . By encompassing this from several sides, the core 3 is held elastically resiliently by the jacket 4 . As a result, the elastic or resilient effect of the core 3 and the jacket 4 is brought together in order to arrange the knurl 1 in the central recess 8 for receiving the knurl 1 in the core 3 in a manner such that it cannot rotate. In Fig. 1, the elevations and recesses on the knurl 1 and the core 3 to form a positive connection to achieve the security against rotation are not shown.

The cylindrical head of the knurl 1 shows an annular circumferential groove 6 , in which, in the assembled state, an annular circumferential elevation 5 on the inside of the core engages in the recess 8 for the knurl 1 . This connection between the annular groove 6 and the annular spring 5 defines, with the resilient action of the core 3 and the casing 4, a latching, releasable connection between the knurl 1 and the rotary knob 2 .

If the rotary knob 2 are withdrawn from the knurled 1, the handle 2 is grasped in any rotational orientation and withdrawn in the longitudinal direction of the knurl 1 of this. As a result, the resistance of the latching connection of annular spring 5 and annular groove 6 must first be overcome before the rotary knob 2 can be finally removed from the knurl 1 .

If the rotary knob can be fitted onto the knurled 1 again, so, the knurl 1 can through the rotationally symmetric design of the rotary knob 2 and the knurl 1 any rotational orientation are used to suspend the knurled to the knob 2 in the longitudinal direction by the knurl 1 in which Central recess 8 is inserted for the knurl 1 in the core 3 and thereby the core 3 is spread by the knurl 1 until the locking connection finally engages. In this state too, the core 3 presses resiliently on the knurl 1 and, in cooperation with the form-fitting connection of the knurl 1 to the rotary knob 2, ensures a twist-proof connection by means of the elevations and recesses correlating therewith. Through this rotation-proof connection of the rotary knob 2 and the knurl 1 , any rotary movement is transmitted directly to the circuit arrangement in the foot region of the knurl 1 and converted there into electrical signals.

FIG. 2 shows the core 3 in a view from the area of the circuit arrangement, that is to say the foot area of the knurl. In the Fig. 2 of the core 3 surrounding sheath has been dispensed to the presentation, as well as to dispense with a representation of a introduced into the recess 8 knurl.

The core 3 shows a central cylindrical recess 8 , which is suitable for positively receiving a knurl in such a way that a rotary movement of the core 3 is directly transmitted to the knurl which is introduced, not shown here. The core 3 additionally shows a slot 7 , which divides the core 3 with the recess 8 in two halves. Through this slot 7 it is achieved that the resilient, elastic effect of the core 3 is increased and thus larger spring travel can be achieved without the need for high forces. As a result, it is possible to use harder and less elastic materials with greater long-term stability for the formation of the core 3 , without the elastic effect being appreciably impaired. In addition, this resilient effect is supplemented by the jacket, not shown here. Both together ensure a secure connection between knurl 1 and knob 2 with the core 3 .

Reference list

1

Knurl

2nd

Rotary knob

3rd

core

4th

coat

5

annular spring

6

annular recess

7

slot

8th

Knurled recess

Claims (8)

1. Encoder for transmitting rotary movements in electrical signals with a knurl ( 1 ) on which a rotary knob ( 2 ) is seated in a form-fitting manner, the positive connection of the knurl ( 1 ) with the rotary knob ( 2 ) by one or more elevations on one and is formed by one or more correlating recesses on the other part and wherein the rotary knob ( 2 ) is a composite piece of a hard, resilient core ( 3 ) for receiving the knurl ( 1 ) and a soft, elastic jacket ( 4 ), which forms the core ( 3 ) encompasses. 2. Encoder according to claim 1, characterized in that the core ( 3 ) has one or more slots ( 7 ) which ensure a resilient enlargement of the recess ( 8 ) for receiving the knurl ( 1 ). 3. Encoder according to claim 1 or 2, characterized in that the knurl ( 1 ) is cylindrical and longitudinal projections are arranged on its lateral surface, which together with the core ( 3 ) ensure an interference fit. 4. Encoder according to one of the preceding claims, characterized in that in the knurl or in the core an annular circumferential groove and or several correlating surveys are provided on the core or on the knurl and that the survey / s in the manner of a tongue and groove connection releasable and intervening. 5. Encoder according to claim 4, characterized in that the survey is a represents a circumferential spring. 6. Encoder according to one of the preceding claims, characterized in that that the jacket has a hardness of less than 50 Shore.   7. Encoder according to one of the preceding claims, characterized in that the core is an injection molded part onto which the jacket has been sprayed. 8. rotary knob for use for a rotary encoder according to the preceding claims, wherein the rotary knob ( 2 ) is a composite piece of a hard, resilient core ( 3 ) for receiving the knurl ( 1 ) and a soft, elastic jacket ( 4 ), the core ( 3 ) encompasses.