NO790630L - DENTAL INSTRUMENT OPERATED BY PRESSURE AIR ENGINE - Google Patents

Description

The present invention relates to a dental instrument which can be held in the dentist's hand and is designed for grinding or polishing a patient's teeth. More specifically, the present invention relates to an improved hand-held dental instrument equipped with a slow air motor for operating a dental

tools for grinding, drilling or polishing teeth. A hand-held dental instrument must first of all have a low weight so that it is easy for the dentist to use. In addition, it must have a low noise level so that the patient does not feel unnecessary restlessness or discomfort, and the instrument must also be reliable and easily repairable.

There are currently mainly two types of hand-held dental instruments, namely a type with a relatively slow motor (5,000 - 13,000 revolutions per minute) and another type with a very fast motor (approx. 20,000 - 500,000 revolutions per minute). my.). Common hand-held dental instruments with a slow compressed-air motor have various design weaknesses. With normal constructions of this type, it is difficult to arrange a cylinder eccentrically in relation to an engine housing, and exact working function and setting cannot be achieved. As there is furthermore a high flow resistance in the compressed air ducts with such a motor of conventional design, the necessary high torque for dental treatment cannot be achieved simply by lowering the rotational speed of the compressed air motor. In order to produce the high torque required for operation of the dental instrument in question,

a small air turbine driven at very high speed has therefore been used. The effect thus achieved at high rotational speed was then transferred to a reduction drive, e.g. with planetary gears, for reducing the rotational speed to a suitable value for operating the dental tool in question.

An instrument of conventional design must therefore be equipped with a gear coupling for reducing the rotational speed and connected to the rotor shaft for the air motor inside the instrument's handle, while a claw coupling or holding device is arranged for attaching the relevant tool, such as e.g. a tooth grinding wheel. In a dentist's instrument of the usual type, the rotor of the compressed air motor and the claw coupling are thus separated from each other by an intermediate reduction drive.

As the reduction drive is placed inside the handle, this must necessarily be bulky and have considerable weight, so that the dentist finds it inconvenient to treat the instrument. Furthermore, the sound from the gear drive will easily cause a patient to feel uneasiness and discomfort. In addition, malfunctions often occur in the gear drive, which thus requires frequent repairs.

On this background of prior art, it is an object of the present invention to provide a hand-held dental instrument of a construction which is capable of providing high torque directly from relatively slow rotation of a compressed air motor,

without the need for a reduction coupling. With such a construction where the compressed air motor's rotor shaft is directly connected with a claw coupling, the disadvantages of the usual previously known instruments can be eliminated.

The invention thus relates to a dentist's instrument which is driven by a slow-running compressed air motor and whose distinctive feature according to the invention consists in that the instrument in combination comprises a handle which is made up of a housing which contains a pressure motor and a claw coupling for clamping a dental treatment -tools, e.g. for tooth grinding or drilling, in a position concentric with the motor's rotor, said motor housing having a front and a rear chamber and said front chamber containing several channels for the supply and discharge of air and which are formed by longitudinally protruding parts on the inside of the housing, and a cylinder arranged eccentrically in the front chamber and equipped with air inlets and air outlets corresponding to said air channels; a rotor arranged rotatably in said cylinder and with a rotor shaft projecting from the casing; a valve tube with passages for the supply and discharge of air in connection with said channels in the front chamber as well as mounted in the rear chamber, and hoses for supply and discharge of air in connection with said channels for air supply and air discharge respectively.

The dentist tool, such as can be a grinding or polishing tool, is here connected directly to the rotor shaft by means of a claw coupling or a transmission shaft at an angle.

The valve pipe is mounted in the rear chamber in the engine housing of a

in such a way that it can assume three positions, namely a normal position where the channels for air supply and air discharge which are arranged in the valve tube are connected to the corresponding channels for the supply and discharge of air in the front chamber respectively, a blocking position where the channels are blocked off of the rear end surface of the housing, as well as a reverse position where the valve pipe's supply channel is in connection with the channel for air discharge in the front chamber, while the valve pipe's discharge channel is in connection with the channel for air supply in the front chamber. The normal position is intended for use of the instrument during normal treatment, while the reverse position is used by left-handed dentists or when the tool has been removed from the rotor axis.

The rotor, which is arranged in the cylinder, is equipped inwards from its outer surface with radial grooves into which the rotor blades are slidably inserted. The rotor is also equipped with bypass passages for the introduction of compressed air into the bottom of the grooves on the air supply side, which that is to say in the upper position of the leaves, so that the leaves

rotation can be accelerated.

For dental treatment using the present instrument according to the invention, compressed air is forced from the valve passage into the motor housing's air passage and therefore through the inlet into the cylinder for turning it by the compressed air being brought to act on the rotor blades. As the rotor rotates, air will flow from the outlet in the cylinder into the air discharge channels.

The rotation of the rotor axis is transferred directly to the instrument's tool axis, or through an angled shaft to the tool, so that the tool in question can rotate at the same speed as the rotor. As the air ducts according to the invention are arranged along the inside of the engine housing by means of projecting parts whose height is mutually different, the air will flow evenly and freely through these ducts without being weakened by flow resistance. A cylinder with uniform wall thickness can be arranged eccentrically in relation to the housing within a number of parts that protrude from the inside of the housing. A more accurate processing and placement of the cylinder can then be achieved, compared to what is possible with a conventional cylinder with varying wall thickness, so that the cylinder can be placed eccentrically in relation to the engine housing. Air friction loss will thus be reduced to a minimum, which leads to improved efficiency for the rotor. A high torque for the rotor can thus be achieved at a relatively low rotational speed.

It will thus not be necessary to bring the air motor to rotate at a high speed and then to lower the rotation speed by means of a reduction coupling, as is the case with ordinary constructions of this kind.

As the rotor effect at a relatively low rotational speed in the present case can be transferred directly to the processing tool, this tool will rotate with high torque and speed in synchronism with the rotor speed, no gear exchange will thus be necessary to reduce

the rotor speed.

The instrument according to the invention can thus be made with little weight and a short length, compared to conventional designs which are equipped with a reduction drive.

As no gear exchange is used, the number of components that make up the present instrument will be significantly reduced. It will thus be significantly easier) to produce the present instrument and there will be no operational difficulties in connection with gear exchange. Furthermore, unpleasant gear noise will not be produced.

Since air passages are also arranged for the introduction of additional air to the outer ends of the blade grooves,; the rotor can also start up faster, which also means a further increase in the torque.

The invention will now be explained in more detail with the help of execution examples and with reference to the attached drawings, on which: Fig. 1 is a perspective sketch of the dental instrument according to the invention, Fig. 2 shows a longitudinal section through the instrument with the claw coupling in the open position ,

Fig. 3 shows a section along the line III-III in fig. 2,

Fig. 4 shows a section along the line IV-IV in fig. 2,

Fig. 5 shows a longitudinal section through the front part of the instrument with the claw coupling in the locked position,

Fig. 6 shows a section along the line VI-VI in fig. 5,

Fig. 7 shows a section along the line VII-VII in fig. 5,

Fig. 8 shows a section of the same kind as fig. 3, but with the rotor 1 in reverse position, Fig. 9 shows a section of the same type as fig. 4, but in a position corresponding to the reverse position of the rotor, Fig. 10 is a section of the same type as fig. 6, but shows a closed position, and Fig. 11 is a perspective sketch of another embodiment according to the invention, the instrument being shown used together with an angle transmission.

In the drawings, the different reference numbers have the following meaning:

A is a grip,

10 is an engine house,

2 is a cylinder,

3 is a rotor,

4 is a holder,

5 is a valve pipe,

6 is an air supply channel,

7 is an air discharge channel,

8 is an inlet opening,

9 is an outlet opening,

3' is a rotor shaft,

a is an atrium,

a' is a posterior chamber,

20 is a blade track,

21 is a rotor blade,

24 is a passage,

24' is a bypass,

28 is a compressed air duct,

29 is a discharge channel,

31 is an air hose,

32 is an outlet hose,

4 0 is a claw coupling,

B and B' are dental tools,

b is a tool shaft, and

C is an angular transmission.

In fig. 1 in the drawings, it is shown that processing equipment B consisting of a shaft b and a tool b<1>, such as e.g. a grinding or polishing disc, is releasably connected to a compressed air motor contained in a handle A.

Said handle A consists of a cylindrical housing 10 cast in two pieces and of a scope that can be easily grasped by a dentist's hand in the same way as a fountain pen, and contains the compressed air motor. This compressed air engine consists of a cylinder 2, a rotor 3 and a holder 4 as well as a valve pipe 5, as will be seen from fig. 2.

Said engine housing 10 has a front part 10 of smaller extent and which is separated by a partition wall 11 from the main part of the housing. The partition wall 11 is provided in its central area with an opening for a rotor shaft 3<1>.

The housing 10 is equipped with several projecting parts 13 as precursors

in the longitudinal direction on the outside of the housing, so that it does not slip out of the dentist's grip. The housing 10 encloses a front chamber a and a rear chamber a<1>, each of which comprises approximately half of the length of the housing. The rear chamber a' is concentric with the housing 10, which means that the inner cylinder wall of the housing forms the chamber a', as can be seen from fig. 4. A number of protruding parts 14 with mutually different radial extents, however, extend inwards from the inside of the housing into the front chamber 2, so that a cylindrical area 15 is formed which is eccentric in relation to the housing 10, within the row of said projecting parts 14 in the front chamber. Between the projecting parts 14, grooves are formed, of which the deeper grooves serve

as air supply channels 16, while the shallower grooves serve as outlet passages 7.

As will be seen from fig. 3, the inside of the front chamber a on its eccentric side is equipped with a small projecting part 14', so that a groove 16 in a cylinder 2 which is placed in said cylinder-round area 15, can engage with the part 14'.

Furthermore, it will appear from fig. 4 that a projecting part 14' is placed on the inside of the engine housing for attaching a holder 4 in the rear chamber a<1> to the housing 10.

Said cylinder 2 which is placed in the seam is round area 15,

is equipped with air openings 8 connected to compressed air channels 16, as well as with outlet openings connected to the discharge channels 7. As mentioned above, the slot 16 in the cylinder 2 engages with the projecting part 14<*> on the housing 2, so that free rotation of the cylinder 2 is prevented.

The holder 4 is mounted in the end part of the cylinder 2 and is retained by the projecting part 1411. The holder 4 is equipped with a central opening 17 which is concentric with the motor housing 4 (fig. 4). 1 cylinder 2, a rotor 3 is arranged. This rotor 3 is equipped with a protruding axle pin 3' at the front end and a corresponding axle pin 3<1>' at the aft end, these axle pins being led through openings 12 and 17, respectively, concentrically with the housing 10 (fig. 2) . The rotor is rotatably mounted in bearings 18 and 19. Inwards from its outside, the rotor is provided with radial grooves 20, each with its own sliding rotor blade 21. During the rotation of the rotor, these blades are displaced more and less deeply into the grooves 20.

The holder 4 is pressed against the protrusions 14 and against the back of the cylinder 2 by a valve tube 5, which means that the cylinder cannot fall out and the slots are closed. The holder 4 is itself attached by means of the valve tube 5 and its rotation is prevented by the projections 14''. The holder 4 is equipped with passages 22 and 23 which are respectively in connection with compressed air passages 6 and outlet passages 7 and have an inlet 22' and an outlet 23'. At the front end of the holder 4

there are arranged passages which are in connection with the tracks 2 0

in the rotor 3, and through a bypass 24' is connected to the passage 23.

The valve pipe 5 comprises a disc 5' which is slidably mounted in it

the rear chamber a' at the end of a part 5'' which extends to a reduced extent inside the housing 10. As will be apparent from fig. 2, a cap 25 is mounted on the elongated part 5<1>' in such a way that it can be screwed into the housing 10. In this way, the front end of the cap 25 will retain the disc 5' by means of an intermediate gasket 25'.

The elongated part 5' is equipped with a ring 26 with an overlying coupling handle 27 for turning the valve 5. The part 5'' is equipped with a compressed air channel 28 and a discharge channel 29 connected to each opening, 28' and 29' respectively . The openings 28' and 29' are arranged so that when one opening 28' is directly outside an inlet 22', the other opening 29' will be outside the outlet 23' (normal position, fig. 4). However, the disc 5' can also be turned to such a position that the opening 28' corresponds to the outlet 23', while the other opening 29' corresponds to the inlet 22' (reverse position, fig. 9). The disc 5' can also take an intermediate position where the opening 28' does not correspond to any of the openings 22' or 23' (closed position, Fig. 10).

In order to achieve accurate setting of the openings 28', 29', projecting pins 30, 30' are arranged at the end of the holder 4, so that one of these pins can engage with the edge of the opening 29', as will be seen from fig. 4, so that normal position or reverse position for the channels can be achieved. In this connection, a setting instruction showing normal position, reverse position and closed position is also placed on the setting handle 27 and the cap 25. Said channels 28 and 29 are respectively connected to an air hose 31 for the supply of compressed air and an outlet hose 32 for the discharge of air.

Compressed air is introduced into the air channel 28 from the air hose 31, thus

that the air can flow through the opening 28', the inlet 22',

the passage 22 and the passages 6, from which the air will flow into the cylinder 2, as will be seen from fig. 2. Inside the cylinder 2, the air will move so that the blades 21 are brought to set the rotor 3 in rotation. The air will then flow out through the outlet openings 9 and back through the discharge channels 7, the passage 23, the outlet 23', the opening 29', the channel 29 and into the outlet hose (normal position, fig. 4). A continuous supply of compressed air keeps the rotor 3 in rotation and thus also the rotor shaft 3' which is rigidly connected to the rotor 3.

Part of the air in the discharge channel 23 can pass through the bypass

24 and the passage 24' flow into the rotor grooves 20 to thereby accelerate the rotation of the blades 21.

When the valve pipe 5 is set in the reverse position (fig. 9) by means of the control handle 27, compressed air supplied through the hose 21 to the channel 28 will flow through the opening 28', the outlet 23', the outlet passage 23, the discharge channels 7 and the openings 9 into the cylinder 2 in such a way that the rotor 3 is caused to rotate in a direction opposite to that previously mentioned. In this reverse position, the air flows out of the cylinder through the openings 8, the channels 6, the passage 22, the inlet opening 22', the opening 29' and the channel 29. Air can also be fed into the grooves 20 in this reverse position, namely through the passage 24 and the bypass 24', thereby accelerating the rotation of the rotor blades 21.

On the above-mentioned handle A, a claw coupling 40 is mounted which grips or carries a tool B. From the narrower part 10' of the housing, a rotor shaft 3' protrudes which carries a cylinder piece 41, in which in its turn, the axle pin for the tool B is inserted.

The rotor shaft 31 is provided with a transverse locking pin 43 at a location immediately after the cylinder part 41. A locking piece 44 is fitted and a nut 45 is screwed over the cylinder part 41. A clamping sleeve 46 is mounted on the nut 45. Into the narrower part 10' of a clamping ring 48 is screwed into the housing, which is fixed by means of a socket screw 49 and carries the rotor shaft 3', the locking sleeve 44, the nut 45, etc.

The locking sleeve 44, which is equipped with a stop 52, is pushed forward by a spring 50. When the sleeve 44 is displaced rearward, a tooth 51 inside the sleeve 44 will engage the pin 43. The inside of the front end of the nut 4 5 is chamfered, as as shown by the reference number 53, for adaptation to the end of the cylinder piece 41.

The clamping sleeve 46 has a tooth 54' in engagement with a tooth 54 on the nut 45, as well as arms 55 which can slide through a window 56 arranged in the cap 47.

When the clamping ring 48 is pushed backwards by a finger, the clamping sleeve 46 and the locking sleeve 44 will be displaced and the tooth 54' on the sleeve 46 will thus engage with the tooth 54 on the nut 45, while the tooth 51 on the sleeve 44 engages with the pin 43. Furthermore, the arm 52 of the sleeve 44 will penetrate into the opening 56 in the cap 47. The rotation will consequently be prevented (fig. 5-7).

When the clamping ring 48 is turned, the rotor shaft 3' is locked by mutual engagement of the locking sleeve 44, the locking pin 43 and the cap 47, and the cylinder nut 45 is screwed onto the cylinder piece 41 on the locked rotor shaft 43', which causes the nut 5 to shift backwards. When the clamping ring 48 is turned in the opposite direction, the cylinder nut 45 will move forward on the cylinder 41.

When the nut 45 is moved backwards, a bevelled cylinder 51 will be pressed over the cylinder 41, so that the shaft b is connected to this cylinder. When the nut is moved forward, the beveled cylinder 53 will be removed from the cylinder 41, and the shaft b can then be removed from the cylinder 41. After the nut 45 is screwed, if the clamping ring 48 is twisted back, the clamping sleeve 46 and the locking sleeve will 44 return to the original position without further influence, due to the pressure force from the spring 50.

Claims (7)

By thus connecting the shaft pin b on the instrument B to the rotor shaft 3' by means of the claw coupling 40, the rotor power can be transferred directly to the shaft b. Fig. 11 is a sketch showing a tool B' placed on an angle transmission C of a known type. This angular transmission contains a transmission shaft connected to the compressed air motor, so that rotational power from the motor can be transferred to the tool b. This means that the tool's shaft pin b is introduced into the cylinder 41 on the rotor shaft 3' by means of the claw coupling 40 in the manner described above . PATENT CLAIMS. 1. Dental instrument powered by low speed compressed air motor, characterized in that it in combination comprises a handle which is made up of a housing containing a compressed air motor and a claw coupling for clamping a dental treatment tool, e.g. for tooth grinding or drilling, in a position concentric with the motor's rotor, said motor housing having a front and a rear chamber and said front chamber contains several channels for the supply and discharge of air and which are formed by longitudinally protruding parts on the inside of the housing, as well as a cylinder arranged eccentrically in the front chamber and equipped with air inlet and air outlet corresponding to said air channels; a rotor arranged rotatably in said cylinder and with a rotor shaft projecting from the casing; a valve tube with passages for the supply and discharge of air in connection with said channels in the front chamber, as well as mounted in the rear chamber, and hoses for supply and discharge of air in connection with said channels for air supply and air discharge, respectively. 2. Dental instrument as stated in claim 1, characterized in that the longitudinal projecting parts on the inside of the housing protrude to varying degrees, so that the circular cylinder is fixed eccentrically in relation to the housing within a number of such projecting parts. 3. Dental instrument as stated in claim 1, characterized in that the claw coupling is designed so that the dental instrument can be attached or released by means of a simple finger movement of the coupling. 4. Dental instrument as stated in claim 1, characterized in that the dental tool's shaft pin can be attached directly to the motor shaft by means of the claw coupling. 5. Dental instrument as stated in claim 1, characterized in that an angular transmission is connected to the end of the motor housing, and the angular transmission contains a transmission shaft which is connected to the rotor shaft and the dental instrument. 6. Dental instrument as stated in claim 1, characterized in that the rotor is equipped with radial slots with rotor blades slidably inserted into the slots, bypass passages being arranged for the introduction of compressed air into the bottom of the slots on the air supply side, that is to say in the upper position of the blades in the slots. 7. Dental instrument as specified in claim 1, characterized in that the valve tube mounted in the rear chamber can be adjusted so that the channels for supplying air in the front chamber correspond to the discharge channels in the valve tube, while the channels for discharging air in the front chamber correspond to the supply channels in the valve tube, so that the rotor can be made to rotate in a reverse direction.