Manual device for dispensing a pasty filler

Abstract

A manual device, in particular for dental use, for dispensing a pasty filler, may reduce the viscosity of the filler by the introduction of vibrational energy. The device may include a device housing, a detachable container for the pasty filler that includes an outlet nozzle at a front end thereof, a vibration generator with an oscillating body, and pressure generating means for exerting pressure on the pasty filler, wherein the oscillating body is detachably connected to the container in a middle region thereof.

Claims

1. A handheld tool for dispensing a pasty filling material, the viscosity of which can be reduced by supplying oscillation energy, comprising: a tool housing; a detachable container for pasty filling material having an outlet nozzle at a front end; an oscillation generator having a tube-like oscillating body; means for exerting pressure on the pasty filling material, the means comprising a piston chamber and a piston rod, the piston chamber being disposed outside of and adjacent to the tube-like oscillating body, and the piston rod being guided axially through the tube-like oscillating body; a pressure piston disposed in a rear region of the container; wherein the piston rod acts on the pressure piston in the container to dispense the pasty filling material from the container; and means for pre-stressing the piston rod into a starting position, the means for pre-stressing the piston rod being disposed in the piston chamber, wherein the oscillating body is directly connected to the detachable container via a quick-action connection including one or more of a screw connection and a bayonet connection.

2. The handheld tool of claim 1, wherein the means for pre-stressing the piston rod into the starting position comprises one or more spring elements.

3. The handheld tool of claim 1, wherein the outlet nozzle has a conical chamber directed toward the front end of the container and through which the filling material is channeled.

4. The handheld tool of claim 1, wherein the tube-like oscillating body is connected to the detachable container in a central region of the container.

5. The handheld tool of claim 1, wherein the oscillation generator is a pneumatically drivable oscillation generator.

6. The handheld tool of claim 1, further comprising a common pressure supply for the oscillation generator and the means for exerting pressure on the pasty filling material.

7. The handheld tool of claim 1, further comprising a piston disposed in the piston chamber and connected to the piston rod, the piston configured to move the piston rod responsive to compressed air being supplied to the piston chamber.

8. The handheld tool of claim 7, wherein the means for pre-stressing the piston is disposed between an end wall of the piston chamber and the piston.

9. A container for use with a handheld tool for dispensing a pasty filling material, the viscosity of which can be reduced by supplying oscillation energy, the container comprising: a tube-like component designed to accommodate pasty filling material; and an outlet nozzle coupled to the tube-like component for dispensing the filling material, wherein the container has, in a central region of the container, means for detachably connecting the container directly to a tube-like oscillating body of the handheld tool, the means for detachably connecting the container to the tube-like oscillating body including at least one of a screw connection and a bayonet connection, wherein the container has in a rear region a pressure piston for exerting pressure on the pasty filling material, the pressure piston being guided axially through the tube-like oscillating body, wherein the outlet nozzle includes an outlet opening arranged at a front end and the means for detachably connecting the container directly to the tube-like oscillating body is arranged at a rear end of the outlet nozzle opposite the front end, and wherein the outlet nozzle comprises a flange at the rear end, the means for detachably connecting the container directly to the tube-like oscillating body being arranged on an inner surface of the flange.

10. The container of claim 9, wherein the means for connecting the container to the handheld tool comprises a quick-action connection.

11. The container of claim 9 wherein the outlet nozzle has a conical chamber which is directed toward the front end and through which the filling material is channeled.

12. The container of claim 9, wherein the pressure piston is movably disposed within the tube-like component.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention will be explained in more detail in the following text on the basis of the accompanying drawing, in which:

(2) FIG. 1 shows the overall view of a handheld tool according to the invention in a lateral sectional illustration;

(3) FIG. 2 shows an enlarged view of the front end region of the handheld tool with the container for the composite material fastened thereto; and

(4) FIG. 3 shows the container for the composite material in a sectional illustration.

DETAILED DESCRIPTION

(5) The handheld tool according to the invention, which is designated overall by the reference number 1 in the Figures, has an elongate, in particular rod-shaped, tool shaft 2, which is configured in a tube-like manner to accommodate the various components of the tool 1. In this case, an oscillation generator 5 is arranged in particular in the front region of the tool shaft 2 and is coupled via oscillation transmission means to a cartridge 30, which will be described in more detail hereinbelow. The cartridge 30 serves to accommodate and dispense a filling material 50, which can be liquefied by being subjected to oscillations in the audible sound or ultrasound range.

(6) The handheld tool 1 furthermore supports the dispensing of the filling material 50 located in the cartridge 30, for which purpose pressure-generating means 15 are formed in the central region of the tool shaft 2. These pressure-generating means 15, which will be described in more detail hereinbelow, have in particular a piston rod 16 which, during operation of the handheld tool 1, exerts pressure on a piston 40 located in the rear region of the cartridge 30, as a result of which the material 50 located in the cartridge 30 is conveyed to the front outlet opening 36 in an outlet nozzle 35.

(7) A common pressure supply is provided for the oscillation generator 5 and for the pressure-generating means 15. The handheld tool 1 is for this purpose first of all equipped in its rear end region with a coupling part 25, which allows the connection of the tool 1 to a hose which is known per se and leads to a supply unit (not illustrated). The coupling piece 25 can in this case be configured in such a way that the handheld tool 1 is allowed to rotate freely with respect to the supply hose.

(8) The pressure of the compressed air made available by the supply hose is in this case first of all regulated via a pressure limiter 26 arranged in the rear region of the shaft 2. This pressure limiter 26 is set via an operating element 27, for example a setting ring, which is formed on the outer circumference of the handheld tool 1. By rotating this setting ring 27, the pressure can be increased or reduced as desired, and thus the performance of the oscillation generator 5 and of the pressure-generating means 15 can be set. The pressure limiter 26 furthermore ensures that pressure fluctuations that arise in the air supply are equalized, so that a uniform working pressure is permanently provided.

(9) The compressed air, which is set by the pressure limiter 26 to a desired pressure, is then first of all directed via a piston chamber 17 of the pressure-generating means 15 into the front region of the handheld tool 1. Within this piston chamber 17 there is arranged a piston 18, which is connected to the piston rod 16 and is formed in particular as a double piston. The use of a double piston increases the pressure force on account of the application area for the compressed air, increased hereby, so that ultimately the piston rod 16 is pushed forward with sufficient force. Furthermore, a spring 19 is arranged in the front region of the piston chamber 17, this spring 19 being supported both on the front end wall of the piston chamber 17 and on the piston 18. This spiral spring 19 serves as a restoring aid and ensures that after the handheld tool 1 has been switched off, and thus the compressed air has been interrupted, the piston 18 and the piston rod 16 connected to the piston 18 are moved automatically into a starting position. Manual restoring of the piston rod 16 is accordingly not necessary, and so once a new cartridge 30 has been installed on the tool 1, the latter is automatically ready for use.

(10) The compressed air is furthermore also supplied to the oscillation generator 5, which is a pneumatic oscillation exciter, configured in a known manner, for generating oscillations in the audible sound or ultrasound range. The oscillation exciter has a resonant body 6, which is mounted in an elastic manner and supported at its front and rear ends. Furthermore, the resonant body is mounted via appropriate means 7 in the shaft of the tool 1 so that it cannot rotate and is configured in such a way that it is made to oscillate when compressed air is supplied. The resonant body 6 is in this case arranged within a chamber formed by a tube 8, being in turn at a distance from an outer wall of the shaft 2. This allows noise damping during the operation of the oscillation generator 5.

(11) Furthermore, the resonant body 6 is configured as a hollow body, so that the piston rod 16 is guided axially through it. At its front end, the resonant body 6 is coupled to a tube-like oscillating body 10, via whichas is described in more detail hereinbelowthe oscillations are then transmitted to the cartridge 30.

(12) Once the handheld tool has been activated, the oscillation generator 5 accordingly causes the oscillating body 10 to vibrate. At the same time, the pressure-generating means 15 push the piston rod 16 forward, i.e. to the left in the illustrated case, in order to support the dispensing of the composite material 50. It is thus not necessary to actuate the tool 1 separately in order to dispense the filling material 50.

(13) In the following text, the cartridge 30 will be described in detail, this cartridge 30 being intended to be configured in particular as a disposable article. It consists preferably of two elements, a front outlet nozzle 35 and a tube-like component 31, which serves as an accommodating container for the composite material 50. The accommodating container 31 is configured in a hollow-cylindrical manner and is coupled at its front end to the outlet nozzle 35, for example is welded or adhesively bonded thereto or is connected thereto by a press fit. Arranged in a movable manner at the rear end of the accommodating container 31 is a piston 40, which is pushed forward via the piston rod 16 in order to dispense the filling material 50.

(14) For ergonomic reasons, the outlet nozzle 35 is arranged in an angled manner with respect to the container 31. It has an elongate cavity 37, which opens at its front end into the outlet opening 36. The elongate cavity 37 is in this case configured in particular in a conical manner, i.e. has a cross section that narrows increasingly in the direction of the outlet opening 36. The result of this is that, while it is being dispensed, the composite material 50 is continuously subject to shear stress and thus is heated through and liquefied more effectively. Compared to known solutions, in which outlet nozzles or cannulas usually have a cylindrical through-passage opening, improved liquefaction of the composite material 50 during the dispensing phase is accordingly achieved. In this caseas is indicated in FIG. 3the front end of the outlet nozzle or cannula 35 can also be designed in the form of a spherical end region 41. In this case, the outlet nozzle 35 can be used to compact the material already introduced into the tooth cavity by operating the spherical end region 41 that is acted on by sound.

(15) As can furthermore be gathered from the illustrations in FIGS. 2 and 3, the outlet nozzle 35 has at its rear end facing the storage container 31 a flange-like end region 38, which is spaced apart slightly from the outer circumference of the storage container 31. Formed on the inner circumference of the flange-like end region 38 is a thread 39, via which the cartridge 30 can be screwed onto the oscillating body 10, which in turn has a thread 11, so that the configuration illustrated in FIG. 2 is achieved. In this case, it should be noted that, as an alternative to the screw connection illustrated, the cartridge 30 could also be attached to the tool 1 via a bayonet connection or some other suitable quick-action connection. The arrangement of the connecting means in the central region of the cartridge 30 leads to a number of advantages, which will be explained in the following text.

(16) Thus, first of all it is ensured that, on account of the direct coupling of the outlet nozzle 35 to the oscillating body 10 or the arrangement of the thread 39 at the rear end of the outlet nozzle 35, more targeted action of sound in order to liquefy the composite material 50 is achieved. It is in particular ensured that the sound can act on the composite material 50 virtually over the entire section, with in particular the reduction in the cross section contributing thereto, since the material 50 comes fully into contact with the wall of the outlet nozzle 35. Since, furthermore, the storage container 31 is located as far as possible within the oscillating body 10, a smaller region of the surface of the cartridge 30 is in contact with the outer side, and so a noise reduction during operation is achieved. Furthermore, it is not necessary for the wall of the container 31 to be formed in a manner stable under pressure, since it can now be supported directly on the oscillating body 10 and thus absorbs all the pressure forces.

(17) Finally, these advantages lead to it being possible for the cartridge 30 to be configured in a simple manner as a disposable or single-use product. Hygiene regulations, in particular in dental practice, can be complied with without great effort, it being ensured at the same time, however, that the composite material is liquefied effectively during dispensing. This leads to a clear improvement in the operating properties of the handheld tool according to the invention.

(18) In this case, it should be mentioned, in conclusion, that the cartridge according to the invention could of course also be used in handheld tools which do not have means for automatically dispensing the filling material but rather have, for example, a lever mechanism to be actuated separately, as is known from DE 100 01 513 A1. In this case, too, the particular arrangement of the cartridge on the tool contributes to an improved transmission of oscillations.