DENTAL SCALER
TECHNICAL FIELD
This invention relates to electronic dental sealers and more particularly to electronic dental
sealers having a dedicated and integral irrigation supply, a slim handpiece design and means for
alerting a user to sealer tip wear.
BACKGROUND
A dental sealer is an instrument which relies on an angled tip to remove plaque and other
deposits from dental tooth surfaces. One type of sealer relies on an ultrasonic generator to impart
vibration to the tip to enhance the removal process. The tip further includes a passage for
delivering a small amount of water to an opening in an end of the tip which provides cooling of
the tooth surface at the point of cleaning.
Various electronic sealers are known in the art. However, these suffer from various
deficiencies. First, a separate irrigation device is typically required to provide a larger water flow,
which requires the user to switch between instruments. Irrigation devices generally utilize direct
line connections to plumbed water sources, which, because of hygienic concerns, requires
plumbing connections with provisions to prevent back flow into the water supply. Another
disadvantage is that the typical sealer handpiece is fairly large and complex, because it requires water and electrical connections that must retain their integrity through numerous cycles as the handpiece, for sanitary reasons, must routinely be removed and autoclaved.
Another problem with existing dental sealers is the change in cleaning effectiveness with increasing wear of the tip. At present, there is no way to accurately assess this wear as a tip may visibly appear to be adequate while its ultrasonic properties and vibratory response are not.
Consequently, an improved dental sealer is needed to address these problems and offer solutions and improvements.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide a dental sealer handpiece that is slim, having a simplified design which is easier for the user to maneuver in the mouth.
It is a further object to provide a dental sealer with a self contained irrigant for increased portability, and to avoid costly plumbing modifications.
It is yet another object to provide a dental sealer which is capable of delivering irrigants as well as medicaments in the mouth.
It is yet another object to provide electronic monitoring of tip function to alert the user when a tip must be replaced. These and other objects of the present invention are achieved by a dental scaling system comprising a scaling handpiece having a scaling tip at a first end thereof, an ultrasonic transducer in the handpiece, connected to the scaling tip, an irrigant passage passing through the handpiece
to an outlet on the scaling tip, flexible connection means for connecting the handpiece to an
irrigant supply and the ultrasonic transducer to a power supply, the connection means including an
irrigant passage extending therethrough, a housing, a first end of the connection means engaged
to the housing, the housing incorporating the irrigant supply and means for transferring irrigant
from the irrigant supply to the handpiece.
Preferably, the handpiece irrigant passage substitutes for an electrical wire in the hand-
piece, thereby simplifying the design and reducing the overall size of the handpiece. In addition,
optional means for heating the irrigant are included in the handpiece for heating the irrigant as it
passes therethrough to increase patient comfort. Also, the use of a separate, dedicated but
independent irrigant supply avoids complex plumbing connections and allows supplying
medicaments as well as irrigant in the mouth. Electronic monitoring means are utilized to monitor
tip vibratory response and to issue an alert when the tip should be replaced.
BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 is a schematic view of a dental scaling system in accordance with the present
invention.
Fig. 2a is a cross-sectional illustration of a dental sealer handpiece in accordance with the present invention. Fig. 2b is a cross-sectional illustration of an alternative heating element used in
the dental sealer handpiece. Fig. 2c is a cross-sectional view with the heating element removed to
show the ultrasonic transducers. Fig. 2d is a cross-sectional view of an irrigator tip.
Fig. 3 is a cross-sectional illustration of a connector boot for a dental sealer in accordance
with the present invention.
Fig. 4 is a cross-sectional illustration of a connection between the dental sealer handpiece of Fig. 2a and the connector boot of Fig. 3.
Fig. 5 is a side elevational view of a dental sealer handpiece with a scaling tip in accordance with the present invention. Fig. 6 is a cross sectional view of a reservoir bottle, cap, and mounting member assembly for a dental sealer system in accordance with the present invention.
Fig. 7 is a perspective view of a receptacle assembly mateable with the mounting member of Fig. 6.
Figs. 8a and 8b are plan views of progressive stages of mating the mounting member of Fig. 6 with the receptacle assembly of Fig. 7.
.Figs. 9a and 9b are side elevational views of progressive stages of mating the mounting member of Fig. 6 with the receptacle assembly of Fig. 7; Fig. 9c is a top view of Fig. 9b.
Fig. 10 is a schematic illustration of the dental sealer system.
Fig. 11 is a block diagram of the electronics used in a dental sealer system in accordance with the present invention.
DETAILED DESCRIPTION OF THE INVENTION
Referring to Fig. 1, a dental sealer system 1 includes a housing 2 on which irrigant bottles 3 are removably mounted. The housing 2 includes a connector 4 which attaches to a dental sealer instrument 5 by means of a flexible cable 6. The flexible cable 6 has a pair of resilient connector boots 7 and 8 at opposite ends thereof, which slip onto the connector 4 and the instrument 5. The sealer instrument 5 includes a sealer tip 9 and a handpiece 10. The sealer tip 9 is vibrated by an
ultrasonic transducer located inside the handpiece 10. The dental sealer system 1 is powered via a
low voltage electrical power transformer 11 which connects to common house current.
The housing 2 includes an electronics package (not shown) for controlling the ultrasonic
transducer in the sealer instrument 5, which will be discussed below. Means (not shown) are
located in the housing for driving an irrigant 12 from the selected buttle 3, through a dip tube 13,
through the cable 6 to the tip 9 of the sealer instrument 5. Preferably, air pressure is used to drive
the irrigant through the cable. A control panel 14 is located on a front surface of the housing 2,
and there is also a foot pedal 15 connected to the housing 2 for ease in actuating the sealer.
The control panel 14 includes a master power switch 16, and a power indicator light 17.
A control switch 18 is used to turn the irrigation on and off, with the rate of irrigant flow
controlled by a twist knob 19. The irrigant bottles 3 are vented when a button 20 is pressed to
reduce pressure after the procedure is completed to allow the irrigant to flow back to the bottle so
as to prevent dripping during disconnection of the handpiece from the cable. The irrigant bottle in
use is selected by pressing an irrigant bottle selector button 21. Indicator lights 22 located over
the bottles 3 indicate which of the irrigant bottles is in use. A practitioner, by pressing the irrigant
selector button 21, may select between, for example, one bottle 3b containing water 23 and
another bottle 3c containing a medicament 24. For purpose of this application, the term "irrigant"
will include liquids such as water, liquid medicaments, and combination thereof. Each of the
bottles is releasably attached to the housing 2 via a docking assembly 25. The level of energy
supplied to the ultrasonic transducer is adjusted using up/down buttons 26 and this level is
indicated on a display 27. Irrigant or ultrasonic energy are supplied to the sealer tip 9 only when
the foot pedal 15 is depressed, freeing a practitioner's hands for other tasks.
The dental scaling system of the invention contemplates use of a dedicated scaling instrument with irrigant supplied as a lubricant or tooth surface coolant, though without irrigant heating, or use of a dedicated irrigator, with or without heating of the liquid passing therethrough, or use of an instrument that provides both scaling and irrigator functions, and includes an irrigant heater. Such handpieces are readily interchangeable in accordance with the present invention
A cross section of a dental irrigation handpiece 10 with the tip removed is illustrated in Fig. 2a. Irrigant 12 flows into the handpiece 10 through an axial irrigant inlet channel 28. The irrigant liquid then travels through a spiral path 29 surrounding a heating element 30. After being heated to a comfortable temperature, the irrigant flows out of the handpiece 10 through a forward axial irrigant channel 3. A tip 9a attached to the forward end of the handpiece would have a corresponding channel 32 for delivery of the fluid to an end of the tip, as shown in Fig. 2d. Such a tip provides assurance that irrigant or medicament is delivered to selected areas and surfaces in the mouth. In an alternative arrangement shown in Fig. 2b, the irrigant travels through an axial passage which extends along the entire length of the sealer handpiece, and the axial passage 33 has a heating element 34 coiled over at least a portion of its length.
Referring to Fig. 2c, a dedicated sealer handpiece 10a is shown which has an ultrasonic transducer 35, located in a forward portion 36 of the handpiece 10a. The ultrasonic transducer transmits vibration through the forward portion to an attached tip. In this embodiment, no internal heating element is used, and the irrigant 12 is supplied through an axial passage 37, primarily for cooling the sealer tip, as shown in Fig. 5. The transducer is connected by a pair of
leads 38a and 38b to a connector portion 39 of the handpiece.
Irrigant liquid 12, electrical energy for the heating element 30 or 34 and electrical energy
for the ultrasonic transducer 35 are all supplied to the handpiece 10 or 10a through the connector portion 39.
Referring again to Fig. 2a, the connector portion 39 includes a negative contact tip 40 and a positive contact shoulder 41. The connector portion is common to all handpieces to ease interchangeability, though described here relative to the handpiece 10. The axial irrigant inlet channel 28 extends through the negative contact tip 40, the negative contact tip acting as a carrier of irrigating fluid as well as a carrier of electricity. Thus, wires do not need to extend into the contact portion 39 reducing the overall diameter of the connection portion. The negative contact tip 40 and the positive contact shoulder 41 are preferably cylindrical in shape and coaxial to one another. An o-ring 42 provides electrical insulation between the negative contact tip 40 and the positive contact shoulder 41. Another o-ring 43 provides insulation between the positive shoulder 41 and the handpiece casing 44. These o-rings are made of a resilient polymer material which is substantially non-conductive.
Referring to Fig. 3, the connector portion 39 of the handpiece 10 is connectable to the cable 6 through the resilient connector boot 8. The resilient boot 8 includes a first large diameter cylindrical passage 45 and a second smaller diameter cylindrical passage 46. When the connector end 39 is mated to the connector boot 8 (Fig. 4), the negative tip 40 fits within the smaller passage 46, and the positive shoulder 41 fits within the large diameter cylindrical passage 45. An annular positive electrical contact 47 is mounted in the large passage 45 and is connected to a positive lead wire 48, which extends through the cable 6 to the housing 2. Likewise, an annular negative electrical contact 49 is mounted in the smaller passage 46 and is connected to a negative lead wire 50, which extends through the cable 6 to the housing 2. Preferably these contacts
engage the corresponding portions of the handpiece with an interference fit to assure electrical continuity. A water passage 51 extends through the cable 6 to supply irrigant liquid 12 to the sealer 5 through the axial irrigant inlet channel 28.
Referring to Fig. 4, the resilient boot 8 is shown engaged to the handpiece, the resilient portions of the boot 8 forming a first seal 52 around the negative tip 28 to prevent irrigant leakage, and a second seal 53 to electrically isolate the positive shoulder 41. Preferably, the connector 7 which connects the cable 6 to the housing 2 is identical to the connector boot 8, so that the ends are interchangeable. The housing would of course include an identical corresponding negative tip, a positive shoulder and an irrigant passage. Fig. 5 shows the sealer handpiece assembled to a tip, the irrigant 12 passing within the passage 32 in the tip shown in phantom.
Referring to Fig. 6, the irrigant supply bottle 3 includes a cap 54 with a mounting member 55 which mates with the docking assembly 25 on the housing. The mounting member 55 has a neck 56 having a pair of opposed alignment flanges 57 and a pair of opposed arcuate wings 58, best seen in Fig. 8a. A lever is incorporated with the neck, spaced beneath the wings. Beneath each wing is located a ramped surface 60, which will be described below. An irrigant liquid outlet 61 on an upper surface 62 of the mounting member 55 extends to a dip tube 63. A ventilation duct 64 also extends through the mounting member 55. An inner o-ring 65 and an outer o-ring 66 are located in grooves 67 and 68 respectively, and are concentric with one another for separating the irrigant liquid outlet 61 from the ventilation duct 64.
Referring to Fig. 7, the docking assembly 25 includes a fork 69 with tines 70, and a receiving member 71 which defines a circular bay 72 and an entry slot 73. A surface of the
housing, to which the fork and receiving member are attached, completes the docking assembly, as will be described below. Preferably, the tines 71 are sloped and tapered at a forward portion 74 thereof to ease insertion of the mounting member 41, the tines received by the spacing in the neck 56 of the mounting member. Referring to Fig. 8a, the mounting member 55 has an unlocked orientation wherein the wings 58 span along the tines 50. The pair of alignment flanges 57 are parallel to and received on the tines, allowing the mounting member to be slid along the slot 71, into the bay 72. The bay receives the mounting member therein, at which point the lever is used to rotate the mounting member so that the wings are fully received in the bay on the tines. As the wings move onto the tines, the ramped surfaces 60 beneath the wings engage the tines to force the top surface 62 of the mounting member into close engagement with a receiving surface on the housing, thereby compressing the 0-rings to assure proper sealing. Thus, a quick quarter turn is all that is needed to mount and dismount the irrigant bottles. This allows a quick and easy removal or substitution of bottles, depending upon patient needs. Once the mounting member 41 has been rotated into the locked orientation, the wings 58 engage the curved edges of the bay 72, and the mounting member 55 is prevented from sliding out of the bay 72 through the entry slot 73. Preferably, the bay 72 is circular in shape, and the wings 58 are arcs of a circle concentric with the circle of the bay 72 and slightly smaller in diameter, so that portions of the outer edges of the wings 58 engage the edge of the bay 72. Referring to Fig. 9a, b and c, a receiving surface 74 includes an irrigant port 75 and a vent port 76. The irrigant port 75 is centered over the bay 72 for alignment with the irrigant liquid outlet 61 of the mounting member 55 when the mounting member 55 is received in the bay. The
vent port 76 is off center in a location corresponding to the spacing between the vent duct 64 and the irrigant outlet 61 of the mounting member. As the mounting member 55 is rotated using the lever 59 into the locked orientation, the ramped surfaces 60 on the underside of the wings 58 engage the tines 70 to force the mounting member 55 up against the receiving surface 74. The o- rings 65 and 66 are pressed against the receiving surface 74, sealing a fluid connections between the irrigant liquid outlet 61 and the irrigant port 75, and the connection between the vent duct 64 and the vent port 76.
Referring to Fig. 10, the electrical and fluid systems of the dental scaling system 1 are illustrated. In this figure, the illustrative sealer handpiece 10c performs both the sealer and irrigation function, with irrigant heating. A pressurized air source 77 is in communication with the irrigant bottles 3 through a valve 78 which can switch each bottle between being pressurized and vented through a vent 79. Selection of the vent button 20 (Fig. 1) causes the valve 78 to return the pressure inside the bottles 3 to atmospheric pressure. The pressurized air source 77 pumps pressurized air into the selected bottle 3, to cause irrigant to flow out of the dip tube 13 through a selector valve 80 into the cable 6, where the irrigant is transported through an irrigant passage 81 to the sealer handpiece 10, where the irrigant is heated by the heater 30 and expelled through an irrigant outlet 84 in the sealer tip 9. Handpiece control electronics 85 control the electrical energy provided to the heater 30 and the ultrasonic transducer 35. The handpiece electronics 85 are connected through the connector 7 (Fig. 1) to the positive and negative lead wires 48 and 50 of the cable 6. The various switches and controls described relative to the sealer are actuated through the handpiece electronics 85 and these are conventional within the art. The dental sealer system also includes, within the electronic package, novel means for
monitoring tip wear. The electronics package includes means for monitoring the resonance frequency changes in the tip, comparing the initial resonance frequency of the tip when used to the
tip as it ages. When the resonance frequency reaches an upper limit, an error signal is generated
which activates a switch, initiating either a visual or audible signal so that the user will know the
tip must be replaced.
Referring to Fig. 11, when a tip is placed in the hand piece and the ultrasonic transducer is
powered, a frequency analyzer performs a scan over a prescribed frequency range, typically from
about 40 to 50 Khz when using a titanium tip. The range is generally chosen to correspond to a
working frequency range of the tip. By scanning over the frequency range, the resonance
frequency of the tip is located. If the resonance frequency is not found, a second scan is
performed through an increment loop counter. If after the second scan, the resonance frequency
is not found, a "check tip" signal is initiated.
If the resonance frequency falls within the range of about 40 to 47 Khz, the handpiece and tip operate normally. However, if the resonance frequency is either out of the full scan range, or
over a prescribed limit such as 48 Khz, then the "check tip" signal is initiated. If desired, the
transducer power can be terminated pending replacement of the tip. Utilizing such a system
optimizes sealer performance by timely changing of a worn tip.
Although the invention has been described in terms of particular embodiments and
applications, one of ordinary skill in the art, in light of this teaching, can generate additional
embodiments and modifications without departing from the spirit of or exceeding the scope of the
claimed invention. Accordingly, it is to be understood that the drawings and descriptions herein
are proffered by way of example to facilitate comprehension of the invention and should not be
construed to limit the scope thereof.