NO135426B - - Google Patents

Abstract

Process for the preparation of pastes from mechanically foamable powders based on vinyl chloride homo- or copolymers.

Description

Dental residency.

The present invention relates to an air-driven dental drill with ball bearings and control devices for the same.

The purpose of the invention is to provide

a dental drill that vibrates and is as quiet as possible, provides the greatest possible torque with as little air volume as possible, drills as quickly as possible while generating the least possible heat and that lubricates as efficiently as possible with a mixture of air and atomized lubricant that passes through the bearings after passing through an air turbine, that a long service life can be expected without excessive wear of the bearings.

Another object of the invention is to

provide a dental drill which can be operated at all the various speeds required by a dentist and is provided with a suitable supply source of air, water and atomized lubricant, such that the drill is driven by clean, dry air containing the atomized lubricant, holes being processed are cooled by means of an air stream which is directed into the hole on all sides of the drill, has a conical shape and contains water of a suitable temperature, which stream is supplied automatically as soon as the drill is started; the drill is controlled by the dentist's foot in such a way that it can be stopped at the same time as a stream of air can be directed into the hole to clean it, whereby the hole can be inspected and drilling continued without the drill being removed from the mouth.

The invention shall be described in more detail

with reference to the drawing, where fig. 1 shows a side view of an air-driven drill according to the invention, fig. 2 is a side view of an air turbine unit removed from the holder, FIG. 3 is an enlarged plan view of the drill head, and fig. 4 an enlarged end view of one of the ball-

the warehouses; fig. 5 shows a side view on an enlarged scale of one of the ball holders, fig. 6 a section along the line 6—6 in fig. 7, fig. 7 a section along the vertical axis through the head of the drill and the turbine on an enlarged scale, fig. 8 is a front view of a control device, and fig. 9 a view of the back of the control device; fig. 10 shows a connection diagram for the control device, fig. 11 a side view partially in section of a lubrication device, fig. 12 and 1'3 sections along the lines 12—12 and 13—13 respectively in fig. 11 and fig. 14 a section along the line 14—14 in fig. 12.

In fig. 1-3, 30 is an air-powered dental drill having a tubular shaft 31 which is bent at 32 and is provided with a head 34 which is attached to a tubular neck 33.

The size of the hand drill is mostly shown in fig. 1; the other figures show the device enlarged twelve times, but the invention can also be adapted for miniature drilling machines, where the head is somewhat narrower and 7 mm shorter.

A pipe 144 for water and a pipe 145 for air are attached to the neck 33 of the shaft;

these pipes end in orifices which direct air or water into the hole; the pipes 144, 145 go into the shaft 31 which also contains an air-carrying pipe connected to the hose 466, an exhaust pipe for air connected to the hose 561, as well as a cooling water pipe 144 and cooling air pipe 145 which are connected to the hoses 144a and 144b respectively .

An electric line 144c contains two conductors and serves to carry current to the pipes 144 and 145 in the shaft 31, which are heated by their internal resistance.

The head housing 34 is provided with a lid 48 with threads; a turbine unit 58 can be removed from the housing by unscrewing the lid 48 so that the turbine can be easily replaced.

It appears from fig. 2 that the turbine unit 58 consists of a light, thin and cylindrical metal shell 67 which is in contact with a stator 77 at its upper end, and that the stator rests against the outer part of the upper ball bearing 11:3. The turbine is supplied with air at 138 and the air is discharged at outlet 110; the inlet and outlet are in connection with the inlet and outlet pipes in the shaft 31.

The shell 67 rests against the outer part 61 of the lower bearing, and a hollow shaft 39 (Fig. 7) is placed in this ball bearing and has a truncated cone-shaped enlarged part 65 at its lower end and a threaded flange 102 at its upper end. The head housing 34 is provided with a circular opening 38 at its lower end; this opening is placed at some distance from the shaft's truncated cone surface 64, so that an annular nozzle 66 is formed which directs air towards the drill or tool which is placed on the shaft and so that the air jet takes on a conical shape.

The shaft 39 is provided with a cylindrical bore 42, where a tube 43 of plastic, preferably of Teflon, is retained by friction. The shaft is also provided with an inner cylindrical bore 44 which fits a drill stem in such a way that the drill is sufficiently fixed by friction to be driven, while at the same time it can be removed by pulling out by hand or by inserting a needle through the upper opening 50 in the lid 48 of the housing 34.

It appears from fig. 7 that the shaft is provided with a conical surface 64 at its lower end and that the housing has an inner conical surface 63 which extends to the annular nozzle 66. This annular opening 66 is in connection with the outlet opening 109 for the air through the lower bearing and channels 125, 126 through the outer part of the bearing.

The air that passes through the conical nozzle 66 with the conical head 65, and the cooling water that comes out of the tube 144, is also directed towards the shaft and the drill in such a way that the water is atomized and mixed with the air and sprayed onto the drill and into the hole from all sides.

The shaft 39 has an outer cylindrical part which is located in the lower bearing's inner part 96 and a ledge which rests against the bearing part's lower end surface 97; the inner part of the second bearing rests against the annular end surface 92 of the rotor 90. The rotor has a central cylindrical part 93 and an upper tubular part 91.

The end of the rotor's upper annular

part 91 rests against the lower edge of the bearing's inner part 100, the upper edge of which lies against a metal disk 104 which is clamped against the rotor and the inner parts by means of a screw 102 with a flange which is screwed into the end of the shaft 101. The screw 102 has a sharp lower end 132 which presses against an inclined surface 131 on the upper end of the Teflon tube 43 when this is forced into the hole 42 in the shaft by means of a suitable tool.

The tube 43 has an extended end portion which is located in a bore 130 and on one surface 131 and on the other side against a shoulder 129. The Teflon tube will thereby be held sufficiently so that it is held in place when the drill is inserted into or removed from the head; at the same time, when it needs to be replaced with a new one, it can be easily pulled out using a suitable tool.

The shell 67 can be pushed into the cylindrical bore 45 in the housing 34 and is provided with an outward facing cam 72 which slides in a vertical slot 73, so that the shell 67 is prevented from turning; the inlet 138 and the outlet 110 are in connection with the inlet pipe 139 and the outlet pipe 140 in the neck 33 of the shaft.

The cylindrical part 83 of the rotor is provided with a series of slots 108 which essentially run axially and are curved backwards in relation to the direction of rotation at the upper and lower ends of the rotor.

The slots 108 can be produced by means of a tubular cutter having a sufficient diameter for the curved slots 108 to be produced when the cutter works and removes the material on one side of the pipe, while the opposite side of the tool is at some distance from the cylindrical body as a result of this curvature.

Air can be led in at the upper side of the slits 108 and gets the opposite direction as it drives the rotor 90, to finally come out at the lower ends of the slits 108. In the example shown, two to thirty slots are used, and the periphery 107 of the rotor blades lies quite close to the inner surface of the shell 67, so that while they clear the shell, they are effectively closed on the outside of the shell.

The rotor does not rotate until the stator 78 is provided with an annular recess 79 which directs the air to all sides of the rotor; this recess is in connection with the inlet 138. The stator 78 has an upper flange 77 that fits in the housing 34 and a bore 84 that fits the outer part 113 of the upper bearing.

The stator 78 is provided with a lower flange 80 with a series of straight slots 87 which are evenly distributed around the periphery and run diagonally as shown in fig. 7, so that the slits 87 direct the air towards the rotor and towards the direction of rotation.

The stator is provided with a central bore 82 which provides clearance for the rotor and allows air containing atomized lubricant part to pass upwards between the rotor and the stator through the upper ball bearing and out through the opening 50. Air from the outlet chamber 109 below the rotor also passes through the lower ball bearing and out through the annular, conical nozzle 66 which conveniently has a larger cross-section at its lower end; the air containing lubricant thereby continuously lubricates the bearing when the rotor is driven.

Both lowers are of the type that have a smaller number of bullets 57 or 61 than is required to fill the grooves; the balls are kept at the correct distance from each other by means of a holding device 133 which consists of a tube of nylon which runs freely between the outer and inner parts of the bearings and provides a sufficient opening for air with lubricant to pass; each holding device 133 is provided with a cylindrical bore for each ball and a slot 115 which is open towards the end of the bearing. The slots have a slightly smaller width than the diameter of the balls, so that the balls can be placed in the holder by pressing the walls of the slots apart; these slotted wall parts are springy and return on their own, keeping the balls in place.

The radius of the balls is smaller than the radius of the grooves and smaller than the radius of the ball holes in the nylon holding device, so that the balls only come into contact with the grooves and the holding device at points, whereby the friction is minimal.

The holding device prevents the balls from coming into contact with each other and ensures that the lubricant that settles on the balls in the form of a film is spread out.

The construction of the ball bearings is shown in fig. 4, 5 and 6.

Fig. 8 and 9 schematically show a front view and a view respectively of the back of a control device for the handpiece, which provides drive air mixed with atomized lubricant part, cleaning air and filtered water which is used as coolant.

The control device 220 is provided with an inlet 231 for water, which leads to a filter 232 where dirt and other particles that can clog the channels in the device are removed. From the filter the water goes to a pressure control valve 234 which keeps the water pressure at a suitable level and directs it to a solenoid coil valve 226, through a needle valve 228 and to the pipe 144 which directs the water to the nozzle of the drill through suitable electrically heated channels in the shaft.

There is also an inlet for compressed air at 236; the air is obtained from an electrically driven compressor and passes through a separator that removes condensed water. The air is directed to a filter 238, where dust particles that would otherwise affect the operation of the air turbine are removed; the filtered air is passed on to a compressed air control valve 222 which keeps the air pressure at a suitable level and makes it possible to set the pressure manually, so that the turbine speed can be set from zero to maximum. The air then passes through a channel that is controlled by an electromagnetic valve and is led through another channel to an electromagnetic valve 225 which regulates the supply of the air that blows chips away.

A needle valve 229 controls the pressure and quantity of the cleaning air. The driving air coming from the electromagnetic valve 224 is directed to a spray device 243 for lubricant. This atomizing device is provided with a container 244 for liquid lubricant which is atomized through a hose and led by the air to the inlet 138 in the handpiece.

The electromagnetic valves are magnetized and controlled by means of a manual rotary switch 227 and a foot-controlled switch 255 which are parts of the electrical control circuit according to fig. 10. The electrical circuit comprises a rotary switch 227 which is placed in the current-carrying line 600 and is provided with one position for air supply and another position for shower. The switch is double-sided, with the back holding the rotary contact 621 and the front another rotary contact 619.

The fixed contacts on the back of the switch are designated 607 and 618 and are shown in the switch's open position, i.e. the off position where the electrical connections are broken. Fixed contacts 611, 613, 614 are placed on the front of the switch and are connected in such a way that the electromagnetic valve for the clean air is magnetized in one position, while both the valves for the driving air and the water are magnetized in another position. When the switch is in the zero position, the circuit is open again at 614.

The circuit also includes an electric heating device for air 196 and water 197, consisting of resistance tubes in the shaft which are in connection with the air and water nozzle pieces 145 respectively. 144. These electric heating devices are fed from the secondary windings of transformers 602 W for water and 602 A for air.

When the rotary switch is closed, the drive can

the electromagnetism of the air and the purge air

netic valves are controlled by a foot operated switch 255 which is normally held in the open position by means of a spring; drive air and water are turned on when contact 595 is closed and pure blue

air when contact 593 is closed.

The handpiece is thus supplied with heat

met purge air for cleaning the holes;

this cleaning air can be switched on by means of the foot-operated control device 255 as soon as the handpiece has been stopped by the driving air and water being shut off and while the handpiece is still in the mouth, whereby the hole is blown clean; tooth-

the doctor can then continue drilling by turning off the purge air with the help of the foot and switching on the drive air.

Fig. 11-14 shows how atomization

the device for the lubricant is constructed. The atomizing device is placed in the joint

ning for drive air that goes to the inlet on

the handpiece and, as mentioned, has the purpose of mixing the drive air with atomized lubricating

means for lubricating the ball bearings.

In the figures, 512 denotes a snake

which conducts compressed air and atomized lubricant

agent from the upper atomization chamber 505. The lubrication device consists of a plastic

body 468 with a bore 472 and a metal

plug with an internal bore 481. Metal

the plug 474 is closed by a lid 483 and is also provided with an oil pipe 479 which is led down into a transparent oil chamber 478.

The body 468 is provided with a re-

continuous bore 469 with inlet 464 and outlet 470. Between these is placed a metal plug 474 with a nozzle part 495

which is equipped with a central oil nozzle

piece 501 directed towards the outlet and which at 503 is in connection with an opening 486

with a conical valve 492 that controls the quantity

that of the oil coming from the opening 484; this opening is in connection with the bore 481 which is supplied with lubricant through the pipe 479.

The other channel 476 leads from in-

barrel 464 downwards into the oil container at 533 and thereby puts the oil under pressure.

The mouthpiece device 495 is for

synt with flat sides 498, 499 which conduct air on both sides of the oil nozzle 501 and form a venturi nozzle which draws the oil out of the nozzle 501 and atomizes it. Air and atomized oil flow out at 470 and are led by a plastic tube 508 to a separator 505 where oil droplets are collected.

When the compressed air is connected, the venti-

len 526 pressed against the seat 529 at the bottom of the oil separator compartment, but when the compressed air

is closed, the ball valve 526 drops down to a square opening, so that the oil can flow back to the container 478.

To ensure that lubricant is supplied

as soon as the handpiece is started, a further nozzle 650 is placed in the tube 508 comprising a rigid tube with a

lowering 651 along the periphery, as the spring 652 holds the nozzle 650 in place in the

right 508.

The mouthpiece 650 has a small opening

658 at its upper end where lubricant collects and is held when the handpiece stops

can be seen by switching off the drive air. When the air is switched on again, the lubricant is sprayed

part located above the opening 658

instantly and lubricates the handpiece's bearings.

The device described above

provides the dentist with an air-powered hand drill with high torque and low air consumption;

the speed can be easily adjusted using a foot-operated or manually operated valve; hand-

the drill according to the invention can be operated at speeds just up to 250,000 rpm.

when continuously lubricated.

When the handpiece is started by

the drive air is switched on, lubricant is supplied there at the same time, and cooling air flows out from a conical nozzle on all sides of the

the re-tool; cooling water is also connected and atomized in a vortex of air.

When the handpiece is placed in the mouth,

it can be stopped using a foot-operated device at the same time as the cleaning air is switched on, so that it is unnecessary to

turn a special air blowing device in the mouth; drilling can be resumed immediately by switching off the cleaning air using the foot and switching on the drive air and water. The time required for drilling and grinding

operations, is greatly reduced when a hand drill according to the invention is used,

so that time is saved for the dentist and

the benefit for the patient is reduced.

Claims (9)

1. Air-powered dental drill in the form of a handpiece with ball bearings, where a tube met shaft is in connection with a transversely arranged head, where the shaft is provided with an inlet channel and an outlet channel, and an air-driven turbine unit comprising a cylindrical shell which is placed in the head in such a way that it can be removed and abuts against an annular shoulder at the open end of the head, characterized in that the shell rests at its lower end against an outer part of a ball bearing and at its upper end against a stator ring which is provided with a recess where the outer part of an upper ball bearing is placed, that the head is provided with a threaded cap with air holes which is screwed into the head and clamps the aforementioned ball bearing part, stator, shell and ball bearing arrangement, and that the stator is provided with an annular inlet opening and a series of peripheral slots which run obliquely in the direction of rotation and acts as turbine nozzles, a rotating device comprising a cylindrical shaft on which a tool can be placed and which is provided with a truncated, cone-shaped head at its lower end, which is placed with d clearance in a corresponding opening and forms an annular nozzle at the open end of the head, an inner part of a ball bearing which is placed on the shaft and rests against the cone-shaped head, a rotor comprising a cylindrical body placed on the shaft and provided with a tube shaped extension at each end which abuts the inner part of the ball bearing, as well as a further inner part at the upper end of the shaft, the rotor being provided with a series of inclined, curved slots at its periphery which are supplied with air from said nozzles, whereby the rotor is driven and the air is released out in a rearward direction and below the rotor, a threaded part which is fitted to the shaft and clamps the inner part of the ball bearing and the rotor to the shaft, a series of balls spaced some distance apart in the ball bearings, the balls being held in place by a tubular plastic spacer in each bearing, whereby the spacing devices are provided with a circular bore for each ball and a slot for introducing the balls into the bores, as the distance the north arrangement is clear of both parts of the bearings, and that the shell is provided with an outlet leading to the outlet channel, and that the turbine is supplied with clean compressed air containing atomized cooking oil that drives the rotor and exits in a truncated cone-shaped stream towards the tool for cooling at the same time as it passes through openings in both bearings, whereby the balls and ball bearing tracks are continuously lubricated when the drill is operated at speeds in the range between 200 and 250,000. 2. Air-powered hand drill according to claim 1, characterized in that the ball bearing tracks have a larger diameter than the balls whereby the balls only contact the track in points, and that the balls have a smaller diameter than the bores in the plastic ball holders with which they also have point contact, such that they achieve minimal friction and the greatest possible torque and speed with the smallest possible amount of air. 3. Air-powered hand drill according to claim 1 or 2, characterized in that air is obtained from a control unit which is equipped with an air filter where foreign particles are removed and a pressure control valve that keeps the air pressure constant, but allows it to be set manually for controlling the speed by setting the air pressure. 4. Air-powered hand drill according to claims 1, 2 or 3, characterized in that the driving air is controlled by an electromagnetic valve which in turn is controlled by an electric foot switch, whereby the dentist can switch off the driving air possibly at the same time as another electromagnetic valve is affected so that air is directed to the hole for cleaning it, without the handpiece being removed from the mouth. 5. Air-powered hand drill according to any one of the preceding claims, characterized in that the compressed air passes through a lubrication unit comprising a container where lubricant is under pressure by means of compressed air and is forced through a nozzle into the air stream, the nozzle being placed centrally in relation to the air ducts and atomizes the lubricant which is then directed to the turbine. 6. Air-powered hand drill according to any one of the preceding claims, characterized in that the handpiece is provided with additional channels for air and water which go to separate nozzles for air and water and are directed towards the tool which is placed on the shaft, and that the water that comes from the water nozzle flows together with the air that comes from the cone-shaped end of the handpiece, so that cooling water is directed into the hole and onto the tool. 7. Air-powered hand drill according to any one of the preceding claims, characterized in that the device is provided with electric heating devices that can be set separately and heat the air and water that is discharged through the water and air nozzles, so that there shock does not occur as a result of excessive cooling. 8. Air operated hand drill according to which any of the preceding claims, characterized in that the hollow, tubular shaft is provided with a tubular Teflon bushing that fits exactly in the shaft's drilling and is pressed out into a recess in the shaft by the Teflon bushing being pressed into the shaft against an inclined surface on a part that is provided with threads and is placed on the shaft. 9. Air-powered hand drill according to claim 8, characterized in that the threaded part is provided with a cylindrical bore that passes into the bore of the Teflon tube and ends in an annular seat, so that the stem of a drill can be held in the Teflon tube by friction and passes through this tube to a concentric seat at its end in the threaded part.