DE10212520A1 - Appliance for locating decaying teeth employs oscillating feeler tip of soft material - Google Patents

Abstract

A handle (2) encloses a motor with a drive shaft (5). Probes (1) of various forms, (e.g. with a tip feeler (3) of elastomer or even a tooth brush) can be inserted on the shaft and retained in position by a retainer (10) engaging in a slot (8) in the shaft. The motor imparts an oscillating movement to the probe.

Description

The present invention relates to a device for localizing a diseased tooth, with a button that can be inserted into the oral cavity and that can be placed on a tooth Wears a probe with which the tooth is acted on for the purpose of generating pain can.

Often, a sick tooth causes pain in a jaw area that goes much further than that sick tooth. The reason may be that the tooth is inflamed and the inflammation is on overlaps neighboring teeth in corresponding jaw areas. Also the pain of radiate an inflamed tooth to adjacent areas. So it is often difficult to locate a diseased tooth within an aching jaw zone.

To do this, some dentists hit their teeth and with a hard object observe the patient's reaction. If a stroke hits the sick tooth, then the pain is the strongest. A disadvantage of this method, however, is that it is difficult, for example to hit a molar with the percussion instrument. It was therefore already proposed to produce a pronounced pain by a cold shock. This can however, be very uncomfortable for the patient.

From DE 295 04 079 U1 there is also a probe electrode for checking the vitality of teeth known that a handpiece made of insulating material and an electrically attached has conductive electrode tip. By means of the electrode tip, one can on the tooth electrical stimulus. Depending on the reaction of the tooth nerve to the Electrical stimulus can be used to determine whether the tooth or tooth nerve is healthy or not. However, this device for vitality testing of teeth is disadvantageous in several respects and improvement. The handling of the electrical probe electrode in the oral cavity is diffizil. On the other hand, the action of this probe electrode on the tooth for the Patients be very painful.

The present invention is therefore based on the object of an improved device to locate diseased teeth, the disadvantages of the prior art avoids and further develops the latter in an advantageous manner. Preferably a simple to Manageable and cheap device can be created with the sick teeth easily and so can be localized as gently as possible.

According to the invention, this object is achieved by a device according to claim 1 solved. Advantageous embodiments of the invention are the subject of the dependent claims.

According to the invention, it is therefore provided that the probe piece which can be placed on the tooth a drive can be connected, by means of which the probe in an oscillating movement is relocatable. The probe is placed on the tooth with its contact surface and then set into oscillation. The oscillation causes a gentle pain, based on that the diseased tooth can be easily located.

In a development of the invention, the probe consists of an elastomer. The through the The oscillating movement of the probe is only dampened on the Transfer tooth, which makes the test relatively gentle. Become sick teeth nevertheless lead to a clearly noticeable pain. At least the face forming section of the probe is made of elastomer. Preferably the whole is made up Probe made of elastomer and forms an all-plastic body in the manner of a hammer head, which strikes the tooth under test with oscillating movements.

In principle, the push button and the push button can be designed as separate components, wherein the probe is preferably seated positively on the button. The button can corresponding recess such as a groove, a hole or the like own, in which the probe is positively attached.

In an alternative development of the invention, the probe is cohesive on one Key piece carrier part of the button attached. In particular, the probe can be Component injection molding can be integrally molded on the probe support part of the button.

The probe can basically be set in various oscillating movements. According to an advantageous embodiment of the invention, the probe is in by the drive an oscillating poking or hammer movement substantially perpendicular to that each tooth can be moved. The probe leads a hammering movement across Longitudinal direction of the button. This makes it easier, even difficult accessible teeth such as B. Check molars from the outside. The button is in the Cheek pouch pushed, the key piece transverse to the longitudinal direction of the button on the Tooth acts. In this respect, the probe piece forms a tappet or hammer head that has a direction of action transverse to the longitudinal direction of the button.

In a further development of the invention, the probe can sit on a shaft in a rotationally fixed manner, that forms part of the button and can be driven in a rotationally oscillating manner about a longitudinal axis is. In order to make a pushing movement transversely to the rotationally oscillating movement To make the longitudinal direction of the shaft piece, the probe can at least one, preferably but have a few probe bumps projecting laterally around the circumference of the shaft piece, the rotation of the shaft piece in the direction tangential to the circumference of the shaft piece about perpendicular to the tooth.

According to a further preferred embodiment of the invention, the probe can be on a a shaft that can be driven in the manner of a seesaw. The button performs oscillating Rocking movements, so that preferably at the free, projecting end of the button arranged probe piece transversely to the longitudinal direction of the rocker-like button on the to be tested Tooth can act. The rocking movement can optionally be a rotary movement be superimposed on the longitudinal axis. In this case the probe can be used Have axis of rotation concentric contour, which is independent of the rotational position always transfers the rocking motion to the tooth transversely to the longitudinal axis. In particular, it can Probe be a ring sitting on the drivable shaft.

In an alternative development of the invention, the probe can also be on a plunger sit, which is mounted transversely to the longitudinal direction of the button on this and is driven to oscillate. For example, the probe can be on the end face of the plunger seated cap be formed. The linear reciprocating ram movement does that Hammer or push the probe against the tooth to be tested.

It is advantageous if the button with the probe on a dentist or Patients existing oscillation drive can be plugged. In particular, can be provided be that the button with the probe attached to a handpiece electric toothbrush can be coupled. In particular, the button on the handpiece electric toothbrush can be plugged. With an appropriate coupling piece, in particular, a resilient locking lug can push the button to a hand-side Drive element are positively coupled, which the drive movement of the Handpiece arranged motor transfers to the button. The probe is driven So in a preferred embodiment of the invention by the hand part of an electrical Toothbrush. For this purpose, the button has a drive coupling that connects to the drive train, usually on the front end of the handpiece of electric toothbrushes Transmitter element can be coupled. The button is dependent on the version of the Drive of the electric toothbrush handle designed such that the probe a knocking oscillating movement preferably transversely to the longitudinal direction of the button.

To the oscillation movement of the probe, with which this on the tooth to be tested acts to be able to change, a frequency setting device can be provided with With the help of which the oscillation frequency of the probe can be adjusted. Preferably the drive for the probe can have an electric motor, the speed of which corresponding setting means can be varied so that the Frequency of the oscillating movement of the probe changes.

Preferably or alternatively, the amplitude of the oscillating movement of the Key piece can be set. The corresponding amplitude adjustment device can be designed differently.

In a development of the invention, the drive has an eccentric mechanism, with two interconnected eccentrics, with a first of the two eccentrics from one in its direction of rotation reversible motor can be driven. By switching the direction of rotation of the Motors add or subtract the eccentricities of the two eccentrics, which means that effective eccentricity of the eccentric mechanism and thus the amplitude of the Oscillating movement of the probe is changed.

Another preferred embodiment of the invention is that the drive Eccentric mechanism with an eccentric, whose eccentricity extends along its The axis of rotation changes, the eccentric and a mating counterpart are displaceable relative to each other in the direction of the axis of rotation of the eccentric. Accordingly, the counterpart stands with a less eccentric or stronger eccentric section of the eccentric engages so that the amplitude of the over the Eccentric mechanism generated oscillating movement of the probe is changed. In particular, the eccentric, whose eccentricity changes along its axis of rotation, on a motor shaft of a motor slidably mounted in the direction of the motor shaft sit. If the motor is moved, the effective eccentricity of the eccentric is changed.

Preferably, the drive can also have a crank pin and one transverse to the axis of rotation of the Crank pin movably mounted transmitter, the movement of the Crank pin converts into a translatory oscillating movement and on the probe transfers. Preferably, the crank pin with a transverse to the axis of rotation of the Crank pin slidably guided plunger engage on the button is movably mounted and carries the probe at the end.

A particularly simple embodiment of the drive can also consist in that this has an eccentrically mounted unbalanced mass, which with the appropriate movement Probe set into an oscillatory movement. In particular, the unbalanced mass can a rotating drive element that is flexible or articulated with the Shaft of the motor is connected. In particular, the eccentrically arranged mass sit rotatably on a shaft, which is connected to the drive shaft by means of a coupling Motor is connected, the clutch transmits torque and lateral forces, however Angular deviations between the shaft and the motor shaft in the manner of a universal joint allows.

A particularly simple design in terms of its structure and the number of parts is that the drive is a piezoelectric actuator, preferably one Bending transducer, the movement of which is transmitted to the probe.

Further goals, advantages, features and possible uses of the present Invention emerge from the following description of preferred exemplary embodiments based on the drawings. All described and / or illustrated form Features for themselves or in any meaningful combination the subject of present invention, regardless of their summary in the claims or their relationships. The drawings show:

Fig. 1 shows a schematic longitudinal section through a feeler device for locating diseased teeth according to a first preferred embodiment of the invention, in which a push button of an electric toothbrush can be pushed onto the rotationally drivable drive shaft of said hand portion,

Fig. 2 shows a cross section through the Taststück of the probe of FIG. 1 along the line AA in Fig. 1, which shows the profile of the probe,

Fig. 3 is a fragmentary 1 plan view of the coupling region of the Tastgeräts of FIG. In the direction of arrow B in Fig. 1,

Fig. 4 shows a longitudinal section similar to FIG. 1 by a key top for locating diseased teeth according to another preferred embodiment of the invention, after which the button is pushed onto the rotationally oscillating about a transverse axis of rocking drivable drive piece of the handle of an electric toothbrush,

Fig. 5 shows a cross section through the Taststück of the probe of Fig. 4 taken along the line CC recorded therein,

Fig. 6 shows a schematic longitudinal section similar to FIG. 1 sick by a feeler device for locating teeth according to another preferred embodiment of the invention, after which the button is pushed onto the rotationally oscillating about a transverse axis of rocking drivable drive piece of the handle of an electric toothbrush,

Fig. 7 is a schematic longitudinal section through a feeler device for locating diseased teeth according to another preferred embodiment of the invention, according to which the probe is plugged onto a drivable by means of an eccentric rocker from a hand part,

Fig. 8 is a schematic representation of a to Fig. 7 alternative cam mechanism, which has by reversal of rotation direction change of the eccentricity,

Fig. 9 is a schematic representation of the cam mechanism of FIG. 8, the mechanism being shown in a position of lesser eccentricity,

10 is a schematic longitudinal section, the eccentricity of Fig. With a key top for locating diseased teeth according to another embodiment of the invention, after which the button is pushed onto a rocker from a hand part, which is driven by an eccentric mechanism variable by a displacement of the engine,

Figure 11 is a schematic longitudinal section, which has. By a keyer to locate decayed teeth according to a further advantageous embodiment of the invention, after which the button is pushed onto a handpiece for driving the Taststücks an eccentrically seated on a rotating drive shaft Umwuchtmasse,

12 is a schematic longitudinal sectional view of the Fig. By a keyer to locate decayed teeth according to another embodiment of the invention, according to which the probe has a displaceably guided tappet driven by a piezoceramic bending transducer, and

13 is a schematic longitudinal section which is driven by means of a crank pin FIG. Through a feeler device for locating diseased teeth according to another preferred embodiment of the invention, according to which the probe has a transversely displaceably mounted tappet.

The diseased in FIGS. 1 to 3 shown keyer for locating teeth has a rod-shaped probe 1 which is attachable to a hand part 2 of an electric toothbrush.

The button 1 carries at its front end a button 3 , which consists of elastomer. The button 3 has an overall annular shape and sits in a groove machined into the peripheral side of the button 1 . As Fig. 2 shows the probe 1 is provided in the region of the groove having a non-circular shape in cross section so that the Taststück 3 by positive locking in a rotationally fixed on the push-button 1 is seated. As shown in FIG. 2, the probe 3 has two probe bumps 4 which project approximately tangentially from the circumference of the probe 1 and which form contact surfaces or work surfaces for placement on a tooth to be tested.

The hand part 2 of the toothbrush has, in a manner known per se, a drive shaft 5 projecting on the end face, which is arranged coaxially to the longitudinal axis 6 of the hand part 2 and the push button 1 . The probe 1 has a substantially komplentäre to the drive shaft 5 recess, with which it can be plugged onto the drive shaft 5, namely a form-fitting and rotationally fixed manner. As shown in FIG. 1, a flattening 7 is provided on the drive shaft 5 , which is used for torque transmission. Furthermore, the drive shaft 5 has a transversely extending groove 8 into which a spring tongue 9 with a radially projecting latching hook 10 of the button 1 can snap. The spring tongue 9 is formed by a U-shaped groove 9 a in the drive shaft 5 . It is therefore provided between the button 1 and the drive shaft 5 of the handpiece 2, a releasable interlocking locking.

A motor ( not shown in detail ) is provided in the interior of the hand part 2 , the rotary drive movement of which is converted into a rotationally oscillating drive movement of the drive shaft 5 by means of a gear, also not shown. The drive shaft 5 can thus perform a rotating oscillation 11 about the longitudinal axis 6 of the device.

If the push button 1 with the two tactile bumps 4 of the tactile element 3 is placed on a tooth with the hand part 2 switched on, the tactile bumps 4 bump against the tooth as a result of the oscillation 11 , so that the patient has a harmless pain when the tooth is healthy and a sharper pain when the tooth is sick Feels pain. The pain is kept weak by the elastic probe 3 .

The feeler device shown in FIGS. 4 and 5 is similar to the previously described embodiment of a trigger 1 and the handle 2 of an electric toothbrush. The hand part 2 of the electric toothbrush comprises a housing 12 and a rocker 13 which protrudes from the front of the housing 12 and forms a neck 14 there . An elastic sealing piece in the form of an elastomer bellows 15 is provided between the neck 14 , the rocker 13 and the housing 12 , which enables movements between the rocker 13 and the housing 12 . The rocker 13 is mounted in the housing 12 so that it can be rocked about a transverse axis 16, the rocker bearing being a pin joint, for example. By means of a drive arranged in the interior of the housing 12 of the hand part 2 and not shown in the drawing, the rocker 13 can be driven in such a way that it carries out a rocking oscillating movement 19 about the transverse axis 16 .

As shown in FIG. 4, a drive shaft 17 protrudes from the neck 14 of the rocker 13 at the end, which drives the rocking oscillating movement 19 of the rocker 13 . In addition, the drive shaft 17 can be driven in a rotationally oscillating manner about its longitudinal axis. The drive shaft 17 thus performs two movements. On the one hand, it rotates in an oscillating manner about the longitudinal axis 6 , thus executing a rotary oscillation 11 . On the other hand, it also oscillates about the transverse axis 16 . The drive is preferably carried out by an electric motor arranged in the housing 12 with a corresponding gear.

The button 1 is shown in FIG. 4 designed as a rod and forms a receiving shaft, which can be plugged into a form-fitting and rotationally fixed to the drive shaft 17 of the handle 2. Similar to the embodiment described above, the drive shaft 17 has a flat 7 and a transversely extending groove 8 . The push-on recess in the button 1 is essentially complementary to the drive shaft 17 . By means of a spring tongue 9 , which has a radially projecting latching hook 10 , the button 1 can snap into the groove 8 , as a result of which it is held axially. Torques can be transmitted by positive locking with the flat 7 .

Designed as a round bar switch 1 carries at its front end a Taststück 3, as shown in FIG. 5, is formed as a ring seated in a recess provided on the circumference of groove-shaped recess 18 in the button 1. In this embodiment, the base of the groove-shaped recess 18 can be circular in FIG. 5. The push button 3 , which preferably consists of elastomer, can be an O-ring.

If the button 1 with the button 3 is placed on a tooth with the hand part 2 switched on, the rocking oscillating movement 19 is transmitted to the tooth, so that diseased teeth can be localized by corresponding pain sensation. The circular oscillation 11 is not transmitted by the circular contour of the probe 3 .

The push button shown in FIG. 6 consists of a push button 1 and the hand part 2 of an electric toothbrush, the hand part 2 corresponding to the hand part 2 shown in FIG. 4. In this respect, reference can be made to the description there.

The button 1 comprises a rod-shaped shaft 20 which carries a probe 3 at its free end, which is mushroom-shaped and sits on the peripheral surface of the shaft 20 . The button 3 is also rigidly attached to the button 1 here. However, it is also molded from elastomer so that it is itself elastic.

Toward the hand part 2 towards the shaft 20 , the button 1 has a push-on section 21 in which a cylindrical, stepped recess is provided. On the face side, a profile ring 22 is pressed into the plug-on section 21 , the inner contour of which corresponds to the outer contour of the neck 14 of the hand part 2 and can be attached to it.

In the interior of the plug-on section 21 , a bushing 23 is also loosely received, which is held axially by the profile ring 22 . The socket 23 can be fitted onto the drive shaft 17 of the handpiece 2 with a precise fit. Similar to the previously described embodiment, the bush 23 sits in a form-fitting manner on the flat 7 of the drive shaft 17 and can snap into the groove 8 of the drive shaft 17 by means of a spring tongue 9 and a radially projecting latching hook 10 arranged thereon. The push button 1 is axially secured on the hand part 2 via the socket 23 and its positive locking with the drive shaft 17 .

Due to the rocking movement of the rocker 13 of the hand part 2 , the head of the button 1 and thus the button 3 performs the rocking oscillating motion 19 about the transverse axis 16 . The probe 3 strikes against the tooth to which it is applied. When the handpiece 2 is switched on, the patient feels the oscillation movement 19 as harmless pain in the case of a healthy tooth and as sharper pain in the case of a sick tooth, so that the diseased tooth can be localized. Due to the loose arrangement of the bushing 23 in the plug-on section 21 , the rotational oscillation of the drive shaft 17 is not transmitted.

The button shown in Fig. 7 also consists of a button 1 , which can be attached to the drive element of a handpiece 2 . A rocker arm 24 is provided as the drive element and is mounted such that it can be rocked about a transverse axis 25, for example by a corresponding pin bearing, on a housing 26 of the hand part 2 . The rocker 24 projects from the end of the housing 26 and has a coupling section, in particular a neck 27 a, onto which the button 1 can be plugged in a form-fitting manner.

The rocker arm 24 is driven by an eccentric mechanism 27 , which in turn is driven by an electric motor 28 which is arranged in the interior of the housing 26 of the hand part 2 . As shown in FIG. 7, a roller 29 is rotatably mounted about the longitudinal axis of the rocker 24 at the rear end of the rocker 24 . The swing arm 24 has a pin 30 on the back on which the roller 29 is seated.

An eccentric 32 , on which the roller 29 runs, sits on a motor shaft 31 of the electric motor 28 in a rotationally fixed manner. The rocker arm 24 is pretensioned by means of a spring device, which is formed by a compression spring 33 , so that the roller 29 is pressed against the eccentric 32 . By means of the eccentric drive, the rocker 24 carries out oscillating movements about the transverse axis 25 .

The rod-shaped button 1 , which is attached to the rocker 24 , carries at its front, free end a mushroom-shaped button 3 made of elastomer, which is attached to the button 1 on the circumference.

When the electric motor 28 is switched on , its motor shaft 31 and the eccentric 32 seated in a rotationally fixed manner rotates so that the rocker arm 24 carries out oscillating movements 19 about the transverse axis 25 . The frequency of the rocking oscillation movement 19 corresponds to the speed of the electric motor 28 . Adjustment means are preferably provided for varying the engine speed, so that the frequency of the oscillation movement 19 can be adjusted. It goes without saying that an air motor or a turbine can also be provided instead of the electric motor 28 .

In order to also be able to set the amplitude of the oscillating movement 19 of the rocker 24 , the eccentric mechanism 27 can be replaced by an alternative eccentric mechanism 34 , which is shown in FIGS. 8 and 9. A first eccentric 35 is seated on the motor shaft 31 of the electric motor 28 , on which a second eccentric 36 with a geometric axis 37 is mounted. The roller 29 shown in FIG. 7 is pressed onto the second eccentric 36 . In a position shown in FIG. 8, the eccentricities of the two cams 35 and 36 add. There is an effective eccentricity e1 as the distance between the motor shaft axis 38 and the axis 37 of the second eccentric 36 . In contrast, in a position according to FIG. 9, the eccentricities of the two eccentrics 35 and 36 are subtracted. This creates an effective eccentricity e2 as the distance between the two axes 37 and 38 . Switching between the effective eccentricities e1 and e2 takes place by reversing the direction of rotation of the electric motor 28 . The positions of the eccentric 36 relative to the eccentric 35 are fixed by stops, not shown, which are part of the two eccentrics 35 and 36 .

In the arrangement shown in FIGS. 8 and 9, the user can choose between two effective eccentricities e1 and e2 and thus between two amplitudes of the oscillating movement 19 .

A further embodiment of the invention, in which the amplitude of the oscillation movement 19 can be set, is shown in FIG. 10. The basic structure of the touch device consisting of the push button 1 and the hand part 2 corresponds to that of FIG. 7, so that reference is made to the description there , However, instead of the eccentric mechanism 27 from FIG. 7, the touch device has a differently designed eccentric mechanism 39 . An eccentric 40 is seated on the motor shaft 31 of the electric motor 28 aligned in the longitudinal direction of the feeler device, the eccentricity of which changes in the longitudinal direction of the motor shaft 31 . In a plane 41 , the eccentricity is zero. In a plane 42 , on the other hand, the eccentricity is maximum. As shown in FIG. 10, the eccentricity of the eccentric 40 is continuously, in particular linearly, formed over the length of the motor shaft 31 . It increases from the front end of the motor shaft 31 to the motor housing.

As in the previously described embodiment, the rocker 24 runs with its end-mounted roller 29 on the eccentric 40 . The electric motor 28 is mounted together with the motor shaft 31 and the eccentric 40 non-rotatably mounted thereon in a longitudinal direction 6 a in the hand part 2 . If the electric motor 28 is moved with the eccentric 40 in the longitudinal direction 6 a, the amplitude of the oscillating movement 19 of the probe 3 changes .

The feeler device shown in Fig. 11 consists of a probe 1 which is formed essentially as a hollow cylinder. At its front end, the button 1 carries a button-shaped button 3 made of elastomer, which is attached to the button 1 on the circumference.

The button 1 is seated on a housing 44 of the hand part 2, which is also essentially cylindrical. An electric motor 28 with its motor shaft 31 is arranged in the longitudinal direction inside the hand part 2 . A coupling piece 45 , which couples the motor shaft 31 to a drive shaft 46, sits on the motor shaft 31 of the electric motor 28 . The coupling piece 45 transmits torques and transverse forces, but allows angular deviations between the drive shaft 46 and the motor shaft 31 in the manner of a universal joint. The drive shaft 46 is mounted on the end face in a bearing section 47 of the housing 44 . At the front end, ie near the probe 3 , an unbalanced mass 48 sits eccentrically on the drive shaft 46, which rotates together with the drive shaft 46 and thereby causes an unbalance. The bearing section 47 , which supports the drive shaft 46, is preferably movable relative to a motor housing section 49 of the housing 44 . For this purpose, the housing 44 has an elastic ring section 50 in the form of an elastomer bellows, which connects the motor housing section 49 and the bearing section 47 of the housing 44 .

When the electric motor 28 is switched on , the drive shaft 46 rotates with the unbalanced mass 48 seated thereon, as a result of which the drive shaft 46 , the bearing section 47 of the housing 44 and the button 1 seated thereon perform an oscillating movement 19 around the coupling piece 45 .

As shown in FIG. 11, the probe 3 can be integrally formed on the button 1 in one piece. It is preferably injection molded in the two-component spraying process.

The sick in Fig. 12 shown keyer for locating teeth consists of a substantially rod-shaped probe 1 and a hand part 2, to which the probe 1 can be plugged. The button 1 is designed as a hollow body. At its front end, a plunger 51 is slidably mounted in the push button 1 , in a direction 52 transverse to the longitudinal axis 6 of the push button device. The plunger 51 jumps radially out of this on a peripheral side of the push button 1 and carries a push button 3 on its front projecting head side, which is designed as a button-shaped elastomer head. The probe 3 can be injection molded onto the plunger 51 in a two-component injection molding process.

To drive the plunger 51 , a piezoceramic bending transducer 53 is provided, which is designed as a rod and is attached to the hand part 2 with one end. As FIG. 12 shows, the bending transducer 53 jumps out of the neck of the hand part 2 and extends axially through the interior of the button 1 . With its movable, projecting end, the bending transducer 53 is in engagement with the plunger 51 . The bending transducer 53 is received in a groove 54 machined in the circumference of the tappet 51 .

The piezoceramic bending transducer 53 can be supplied with alternating current in a suitable manner from the hand part 2 , so that it executes vibrations transversely to the longitudinal axis 6 of the feeler device. The plunger 51 , which engages with the bending transducer 53 , accordingly carries out a translatory oscillation movement 19 along the axis 52 .

Fig. 13 also shows a touch probe which has a translationally displaceable plunger. It consists of an essentially shaft-shaped button 1 and a hand part 2 , on which the button 1 can be attached with a sleeve-shaped connecting piece 55 . As FIG. 13 shows, the hand part 2 comprises an essentially cylindrical housing 56 , which can be inserted into the connecting piece 55 with its front end. An electric motor 28 is provided in the interior of the housing 56 of the hand part 2 , the motor shaft 31 of which extends in the longitudinal axis 6 of the hand part 2 . A hub 57 with a crank pin 58 , which protrudes from the end face parallel to the longitudinal axis 6 of the hand part 2, sits on the motor shaft 31 in a rotationally fixed manner.

A plunger 51 is displaceably mounted in the front end of the button 1 , similar to the previously described embodiment, in a direction 52 transverse to the longitudinal axis 6 of the device. The plunger 51 protrudes circumferentially from the button 1 . On the protruding end face of the plunger 51 , a probe 3 is fastened, which is button-shaped and made of elastomer.

As shown in FIG. 13, the plunger 51 has a transverse groove 54 which is introduced on its peripheral side and extends transversely to the direction 52 of the plunger 51 . The crank pin 58 of the drive on the hand part is guided in the transverse groove 54 , so that its circular drive movement is converted into a linear oscillation of the tappet 51 in the direction 52 transverse to the longitudinal axis 6 of the touch device. The oscillation movement of the plunger 51 is identified by the arrow 19 in FIG. 13.

Claims (15)

1. Device for locating a diseased tooth, with a push-button ( 1 ) that can be inserted into the oral cavity and that carries a probe ( 3 ) that can be placed on a tooth and that can be used to act on the tooth for the purpose of generating pain, characterized in that The probe ( 3 ) can be connected to a drive ( 5 ; 13 ; 24 ; 46 ; 53 ; 58 ), by means of which the probe ( 3 ) can be set into an oscillating movement ( 11 ; 19 ). 2. Device according to the preceding claim, wherein the probe ( 3 ) consists of an elastomer, is preferably designed as an all-plastic impact head. 3. Device according to the preceding claim, wherein the button ( 3 ) is integrally molded in two-component injection molding on a button support part of the button ( 1 ). 4. Device according to one of the preceding claims, wherein the probe ( 3 ) by the drive in an oscillating poking or hammer movement ( 19 ) can be displaced substantially perpendicular to the respective tooth. 5. Device according to one of the preceding claims, wherein the feeler ( 3 ) rotatably sits on a shaft piece ( 1 ) which can be driven in a rotationally oscillating manner about its longitudinal axis, and at least one, preferably a few, protruding laterally on the circumference of the shaft piece, bumps ( 4 ) having. 6. Device according to one of the preceding claims, wherein the probe ( 3 ) sits on a shaft ( 13 , 24 ) which can be driven in the manner of a rocker. 7. Device according to one of claims 1 to 4, wherein the feeler ( 3 ) sits on a plunger ( 51 ) which is mounted transversely to the longitudinal axis ( 6 ) of the pushbutton ( 1 ) and can be driven to oscillate. 8. Device according to one of the preceding claims, wherein the button ( 1 ) with the probe ( 3 ) arranged thereon is designed as an interchangeable part and can be coupled to a hand part ( 2 ) in which the drive is provided, preferably to a handpiece of an electric toothbrush The push button ( 1 ) preferably has a coupling piece, in particular a resilient locking lug ( 9 ) for coupling to a drive element ( 5 ; 17 ) on the hand part side. 9. Device according to one of the preceding claims, wherein a frequency setting device ( 28 ) for setting the oscillation frequency of the probe ( 3 ) is provided, wherein preferably the drive for the probe has an electric motor ( 28 ) with adjustable speed. 10. Device according to one of the preceding claims, wherein an amplitude adjusting device ( 34 ; 39 ) for adjusting the amplitude of the oscillating movement ( 19 ) of the probe ( 3 ) is provided. 11. Device according to one of the preceding claims, wherein the drive has an eccentric mechanism ( 34 ) with two interconnected eccentrics ( 35 , 36 ), a first of the two eccentrics ( 35 ) being driven by a motor ( 28 ) which is reversible in its direction of rotation such that the sum of the eccentricities (e1, e2) and thus the amplitude of the oscillating movement of the probe ( 3 ) changes when the direction of rotation is switched. 12. Device according to one of the preceding claims, wherein the drive has an eccentric mechanism ( 39 ) for generating the oscillatory movement, which has an eccentric ( 40 ) whose eccentricity changes along its axis of rotation, wherein the eccentric ( 40 ) and in engagement therewith standing counterpart ( 29 ) can be displaced relative to one another in the direction of the axis of rotation, preferably the eccentric ( 40 ) sits on a motor shaft ( 31 ) of a motor ( 28 ) which can be displaced in the direction of the motor shaft. 13. Device according to one of the preceding claims, wherein the drive has a crank pin ( 58 ) and a transversely mounted to the axis of rotation of the crank pin transmitter ( 51 ) for transmitting the rotational movement of the crank pin ( 58 ) to the probe ( 3 ), preferably the Crank pin ( 58 ) engages with a plunger ( 51 ) which is displaceable transversely to the longitudinal direction of the button and which carries the button ( 3 ) on the end face. 14. Device according to one of the preceding claims, wherein the drive has an unbalanced mass ( 48 ) mounted eccentrically on a rotationally drivable drive element ( 46 ). 15. Device according to one of the preceding claims, wherein the drive has a piezoelectric actuator, preferably bending transducer ( 53 ).