POWDER CLEANER FOR DENTAL USE

Abstract

A powder-cleaning device for dental use is provided. It has proximal arm configured for attachment to a source of compressed air; a distal arm having a distal end configured for dispensing a mixture of air and powder to a patient a turbulence chamber, which has a loading side door configured for insertion of an abrasive powder into the chamber according to a loading direction substantially orthogonal to a plane defined by the prevailing extensions of the arms (DP, DD). The turbulence chamber is interposed between the proximal arm and the distal arm and in fluid communication with both in such a way that the compressed air can be adducted in the turbulence chamber through the proximal arm and a mixture of air and powder can escape therefrom within the distal arm. A controller is also provided for compressed air flow, arranged on the proximal arm upstream of the turbulence chamber.

Claims

1. A powder-cleaning device for dental use, comprising: a proximal arm, configured for attachment to a source of compressed air; a distal arm, having a distal end portion configured for dispensing a mixture of air and abrasive powder; a turbulence chamber, configured to receive the abrasive powder, which turbulence chamber is interposed between said proximal arm and said distal arm and in fluid communication with both in such a way that the compressed air can be adducted in the turbulence chamber through said proximal arm and the mixture of air and powder can escape within said distal arm; a controller for compressed air flow, arranged on said proximal arm upstream of said turbulence chamber, which controller comprises: a plug or pin, which can be selectively translated to occlude a feeding channel of compressed air of said proximal arm, and an actuation element, operable in rotation by an operator, wherein said actuation element and said plug or pin comprise respective shape-coupling surfaces, wherein said controller allows a modulation of said flow rate between a condition of minimum air supply, which optionally corresponds to zero flow, and a condition of maximum air supply, which device is configured as a handpiece so as to be grasped by an operator at said proximal arm or said distal arm.

2. The powder-cleaning device according to claim 1, wherein said plug or pin has a head and a stem.

3. The powder-cleaning device according to claim 1, wherein said plug or pin or said actuation element have a respective shape-coupling surface with a cam or spherical profile.

4. The powder-cleaning device according to claim 1, wherein said actuation element is made in the shape of a ring which is rotatably coupled on an outer casing of said powder-cleaning device.

5. The powder-cleaning device according to claim 1, wherein said actuation element has a shape-coupling surface which forms a shaped guide with a cam profile, and wherein the configuration is such that said shape-coupling surface acts in abutment on a head of said plug or pin, in particular on a shaped surface of said plug or pin.

6. The powder-cleaning device according to claim 1, comprising a dispenser a jet of water, having one or more outlet nozzles at said end portion of said distal arm.

7. The powder-cleaning device according to claim 1, wherein said turbulence chamber has a loading side door configured for insertion of the abrasive powder into the turbulence chamber.

8. The powder-cleaning device according to claim 7, having a geometry such that said turbulence chamber is loadable with the abrasive powder with the powder-cleaning device resting on an opposite side to said loading door and optionally on said proximal arm and said distal arm.

9. The powder-cleaning device according to claim 7, comprising a closing door of said loading side door.

10. The powder-cleaning device according to claim 9, wherein said closing door is openable and closable by means of a screw coupling with an outer casing of the powder-cleaning device, said door being configured as a ring.

11. The powder-cleaning device according to claim 1, wherein said arm proximal and distal arms extend along respective prevailing directions, optionally mutually inclined.

12. The powder-cleaning device according to claim 7, wherein said loading side door is configured in such a way that the powder can be inserted according to a loading direction substantially orthogonal to a plane defined by said first prevailing direction and said second prevailing direction.

13. The powder-cleaning device according to claim 1, wherein said turbulence chamber has a lateral skirt optionally with a cylindrical development, closed on both sides by a respective base or wall.

14. The powder-cleaning device according to claim 13, wherein said turbulence chamber has an overall cylindrical shape.

15. The powder-cleaning device according to claim 13, wherein said respective base or wall has a dome conformation.

16. The powder-cleaning device according to claim 7, wherein said loading side door is formed at said bases or walls.

17. The powder-cleaning device according to claim 1, wherein said turbulence chamber comprises a transparent portion configured to allow an operator to see the inside.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0018] Reference will be made to the figures of the accompanying drawings, in which:

[0019] FIG. 1A shows a side perspective view of a preferred embodiment of the powder-cleaning device according to the present invention;

[0020] FIG. 1B shows a front view of the device in FIG. 1A;

[0021] FIG. 1C shows a rear view of the device in FIG. 1A;

[0022] FIG. 1D shows a bottom view of the device in FIG. 1A;

[0023] FIG. 2A shows a longitudinal sectional view of the device in FIG. 1A, in an open configuration of a respective control valve;

[0024] FIG. 2B shows an enlarged detail of FIG. 2A;

[0025] FIG. 3A shows a longitudinal sectional view of the device in FIG. 1A, in a closed configuration of a respective control valve;

[0026] FIG. 3B shows an enlarged detail of FIG. 3A;

[0027] FIGS. 4A 4B refer to a preferred embodiment variant of the powder-cleaning device according to the present invention, showing each a partial longitudinal sectional view thereof, in an open and closed configuration, respectively, of a relative control valve.

[0028] The dimensions and curves shown in the figures above are to be understood as examples and are not necessarily shown in proportion.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0029] With reference initially to FIGS. 1A to 1D, a powder-cleaning device according to a preferred embodiment of the invention is denoted as a whole with reference numeral 1. The device 1 is intended for dental use, in particular for dental cleaning aimed at eliminating tartar or for other applications as mentioned above.

[0030] Device 1 mainly comprises: [0031] a first arm 2, which will be defined as proximal in relation to its proximity to the operator; [0032] a second arm 3 which will be defined as distal; [0033] a turbulence chamber 4, interposed between the proximal arm 2 and the distal arm 3 and internally in fluid communication with both.

[0034] The aforesaid components are defined by an outer casing 100 of the device and by respective inner elements.

[0035] The proximal arm 2 is configured for attachment to a source of compressed air, in particular by means of a proximal connection 20 of a per se known type and based, for example, on a screw coupling. The proximal arm 2 has an oblong conformation and extends according to a first prevailing direction DP.

[0036] The distal arm 3 also has an oblong conformation and extends according to a second prevailing direction DD which, in the present example, is inclined, that is to say angled, with respect to the first direction DP.

[0037] The distal arm 3 has a distally end portion 30 shaped as a spout or dispensing nozzle and configured for dispensing a mixture of air and powder to a patient, according to modes that will be described hereinafter. Preferably, the end portion 30 is inclined with respect to the second prevailing extension direction DD.

[0038] In the present embodiment example, as will be explained below, a jet of water is also dispensed through the distal portion 30.

[0039] Device 1 is generally configured as a handpiece so as be grasped by an operator at the proximal 2 and/or at the distal arm 3.

[0040] The turbulence chamber 4, in this embodiment example, is defined by a lateral skirt 400, preferably with a cylindrical development, closed on both sides by a respective base or wall 41, 42. In the present example, both bases 41 and 42 have a substantially circular profile seen in plan. One or both of these bases 41, 42 may have a dome configuration. In the variant shown, the turbulence chamber 4 has a substantially cylindrical overall shape.

[0041] The turbulence chamber 4 has a loading side door 40 configured for insertion of the abrasive powder into the chamber itself. At the loading door 40, the chamber 4 can be closed by means of a port, or door 5, which is preferably removable.

[0042] According to the geometry shown, the loading door 40 and the corresponding door 5 substantially occupy the entire base 41, which is therefore defined by the door 5 itself.

[0043] In the present example, the door 5 can be opened and closed by means of a screw coupling with the outer casing 100 in the part in which the latter laterally defines the turbulence chamber 4. In the example shown, therefore, the door 5 is rotatable according to an axis of rotation A. In particular, in the present embodiment, the door 5 is made in the form of a unscrewable ring.

[0044] The axis A is substantially orthogonal, or at least oblique, with respect to plane P defined by the prevailing development directions DP and DD of the arms 2 and 3. Such a plane P is substantially that of representation of the longitudinal sections of FIGS. 2A and 3A. The axis A also coincides, in the present example, also with a loading direction of the chamber 4, i.e. of access through the door 40.

[0045] In the present embodiment, by virtue of the configuration described, the turbulence chamber 4 can be loaded with the abrasive powder, through the door 40, placing the device 1 resting on the side opposite the door 40 itself, i.e. substantially at the second base or wall 42, and preferably also on arms 2 and 3. Other geometries are possible to obtain the same result, according to which the loading operations can be carried out easily, by a single operator who does not need to manually support the device 1 or to have a dedicated support tool.

[0046] Advantageously, the door 5 has a transparent window or portion 50 which allows the operator to view the amount of powder contained inside the chamber 4 and/or the turbulence conditions which are established therein and, in general, to check the local operation of the device 1. In the present example, this transparent window 50 occupies a prevailing area with respect to the plan extension of the door 5 and preferably has a circular profile or in any case corresponding to that of the door 5 itself.

[0047] According to a preferred embodiment, the door 5 has a peripheral gripping portion 51, which in the present example is substantially circular ring in shape. The gripping portion 51 can have radial edges or projections 52 with substantially linear development to facilitate gripping and rotation.

[0048] The door 5, particularly when in the form of a ring, can be made of stainless steel.

[0049] In an application example, the turbulence chamber 4 can be sized for an internal working pressure equal to about 3 bar, with safety sizing at about 9 bar.

[0050] The device 1 of the present embodiment also comprises a flow controller 10, configured to allow a variation of the air flow rate that enters the turbulence chamber 4. The controller 10 is arranged on the proximal arm 2 upstream of the turbulence chamber 4. Advantageously, the controller 10 allows a modulation of said flow rate between a condition of minimum air supply, which preferably corresponds to zero flow, and a condition of maximum air supply.

[0051] FIGS. 2A and 2B refer to a condition of maximum or near maximum flow rate, whereas FIGS. 3A and 3B to a minimum flow condition, which may be in particular null.

[0052] With reference to FIGS. 2A and 2B, the controller 10 is placed at an air feeding channel 21, which passes through the proximal arm 2 to supply compressed air from the coupling 20 to an inlet of the turbulence chamber 4.

[0053] In the present embodiment, the controller 10 comprises a plug or pin 11. The latter has a head 111 and a stem 114.

[0054] The head 111 is provided with a shaped end surface 112, in particular with substantially arched profile and even more preferably with spherical geometry. A seal can be provided at the head 111, in particular an O-ring 113, for example received in a seat formed in the head 111 itself.

[0055] The stem 114 defines a first oblong portion 115 adjacent the head 111, an intermediate portion 116 of reduced cross section and an end portion 117. The transitions between the first portion 115 and the intermediate portion 116 and between the latter and the end portion 117 are defined by local tapered profiles.

[0056] The pin 11 is selectively translatable into a seat 211 of the proximal arm 2 according to a direction T substantially orthogonal to the direction DP and substantially lying on or parallel to the aforesaid plane P. The seat 211 has, in direction T, a first enlarged portion 212 within which the head 111 moves, and a second reduced portion 213 within which the stem 114 moves.

[0057] On the stem 114, in the part closest to the head 111, an elastic return element 120 can be associated, in particular a helical spring. The latter is interposed between a abutment surface of the head 111 and a abutment surface of the seat 211, the latter positioned at the transition between the two portions 212 and 213. The element 120 is configured to counteract the action of an actuation element 12 described below, by pushing the pin 11 into a raised position of greater projection from the seat 211.

[0058] The pin 11 is actuated in translation by the above actuation element 12 which can be operated by the operator. In particular, the actuation element 12, in the present example, is made in the form of a ring which is rotatably coupled on the outer casing 100 of the device 1. Again in the present example, the actuation element 12 rotates about an axis substantially corresponding to direction DP.

[0059] In the arrangement described, the actuation element 12 has a shaped guide surface 121, in particular with a cam profile, which acts in abutment on the head 111, in particular on the shaped surface 112 thereof.

[0060] By such a shape coupling, the pin 11 selectively slides into the seat 211 between a position of maximum air supply, or maximum flow, corresponding to FIGS. 2A and 2B, and a minimum supply position, shown in FIGS. 3A and 3B. In the maximum or non-zero position (FIG. 2B), the intermediate portion 116 of the stem 114 is partially arranged within the enlarged seat 212, allowing the passage of air therethrough, within the reduced seat 213 and then in the portion downstream of channel 21. In other words, the pin 11 is raised towards the outside of the device 1 so as to allow the flow of air coming from the coupling 20 to pass. In the minimum flow position (FIG. 3B), the pin 11 is lowered towards the inside of the device 1. In this position, the portion 115 inhibits the passage of air from the enlarged seat 212 within the reduced seat 213, occluding the feeding channel 21.

[0061] As said, intermediate positions are provided for reducing the air passage area between the lumen portions of the channel 21 upstream and downstream of the controller 10.

[0062] The spring 120 ensures a continuous abutment between the two surfaces 112 and 121, ensuring a return motion of the pin 11 in a raised position towards the outside of the device 1.

[0063] Upstream and/or downstream of the pin 11, non-return flow control means can be applied on the channel 21, such as a valve 22 suitable for preventing backflow of air towards the coupling 20.

[0064] The device 1 also advantageously comprises means for dispensing a jet of water, in particular a channel 7 inside the two arms 2 and 3 and passing through a wall of the turbulence chamber 4. Channel 7 extends between a proximal end configured for attachment to a fluid source and a distal end, arranged at the end portion 30 of the distal arm 3.

[0065] In an embodiment variant, the compressed air feeding channel 21 may be made, at least locally, of deformable material, and the flow control obtained, for example, by means of an outer plug or pin which rests on the channel itself.

[0066] In use, the cleaning device 1 is connected to the dentist's chair or to a different power supply at the coupling 20 and possibly through a connector per se known.

[0067] As said, the turbulence chamber 4 is in fluid communication with both arms 2 and 3, so that the compressed air can be fed into the chamber through the proximal arm 2, with a flow rate managed by the controller 10.

[0068] As soon as the compressed air enters the chamber 4, it creates a turbulence which creates a mixture of air and powder which, being at a pressure greater than the ambient pressure, is directed towards the device outlet through the distal arm 3.

[0069] Varying the flow rate changes the turbulence inside the chamber 4, thus allowing the use of different types of powder.

[0070] Furthermore, the control of the air flow carried out upstream of the turbulence chamber allows the operator to modulate the amount of flow that reaches the patient, without the powder passing through a controlling means and thus avoiding any risk of infiltration or jamming.

[0071] The water, as mentioned, is instead directed directly towards the outlet of the device 1. The above handpiece cleaner may also be associated with a control unit selectively connectable thereto for determining, for example, the state thereof, optionally associated with local sensors.

[0072] FIGS. 4A and 4B refer to an embodiment variant of the device of the preceding figures, which will be described hereinafter solely in relation to the differences with what has already been described. In such FIGS. 4A and 4B, components similar to those already described are denoted with the same numeral reference.

[0073] The difference of this embodiment variant relates to the flow rate control modes.

[0074] In particular, also in this case the flow controller comprises a plug or pin 11 and an actuation element 12 such as those already described, which cooperate by means of a shape coupling.

[0075] In this variant, the stem of pin 11 carries, at the transition between the portions 115 and 116, a further sealing element, such as an O-ring 113.

[0076] In the present variant, at the reduced portion 213 of the seat 211, a hole or passage duct 6 is provided which allows the air coming from the feeding channel 21 to reach the downstream channel, herein denoted by 21, passing precisely through seat 213. This flow is added to that allowed through the passage slot of the enlarged seat 212, the slot herein denoted by 212 and already associated with the embodiment in FIGS. 2A-3B.

[0077] In the open position in FIG. 4A, the air arriving from the feeding channel 21 can pass through both the duct 6 and through the slot 212. In the closed position in FIG. 4B, the air can cross only the duct 6 and thus the seat portion 213.

[0078] Therefore, the provision of the duct 6 allows an additional possibility of control, or calibration, of the air flow.

[0079] Specific implementation methods may also allow an inhibition of passage through duct 6.

[0080] The present invention has been described thus far with reference to preferred embodiments thereof. It is understood that other embodiments may exist that relate to the same inventive scope, as defined by the scope of protection of the following claims.