DE2329728A1 - METHOD AND DEVICE FOR REMOVING LIMESTONE DEPOSIT, IN PARTICULAR TOOTH STONE - Google Patents

Description

September 13, 1973 Dr.Kö / ko

Patent application P 23 29 728.1

National Patent Development Corporation

Method and device for removing limestone deposits _% especially tartar.

The present invention relates to an improved method of removing limescale deposits and dirt, in particular also tartar, and a device for carrying out the method.

In parallel application P 23 29 752.1 filed on June 12, 197 3 the applicant is a method for dissolving or destroying lime or limestone deposits, in particular tartar discloses after which the deposits with an N-haloamine solution can be brought into contact without the need to use mechanical devices.

The present invention relates to improvements in application of the previously mentioned solutions, so that a much faster one through a combined mechanical and chemical action

309882/0551

'REALLY

and more effective disposal can be achieved.

One of the disclosed methods of applying the chemical solutions recited in the above-mentioned application is performed using a WATER PIG ™ machine (see U.S. Patent No. 3,227,158). These devices are in the relevant art for use for oral hygiene - cleaning teeth, massage des Gums and plaque removal - known.

A device of this type has a construction which can be actuated to generate a jet of water that can deliver at 800 to 1600 cycles / minute at a maximum pressure of 90 pounds per square inch through a Nozzle opening from o.o25 to o.o45 inches in diameter pulsates.

According to the principles of the present invention, a significant improvement to achieve a quick and effective removal of deposits or dirt, by modifying the above-mentioned pulsating beam current so that in each pulse cycle the difference between the highest pressure and a reduced pressure exerted on the material correspond to periods in which the material is under the fixed pressure and a decreased pressure causes the material to be mechanically stressed or is tensioned, after which it is completely relaxed, in order to achieve an erosion through fatigue, through which the caries removal is made much easier.

Accordingly, it is an object of the present invention to provide an improved method of applying the above-mentioned chemical solutions on deposit to their full

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FOLLOWED

constant elimination, in particular for the purpose of elimination of tartar.

Another object of the present invention is to provide an improved device for eliminating caries the preparation of the teeth for sealing, the need for drills and the like. Eliminated and the device accordingly the principles mentioned above works.

Another object of the present invention is to provide an improved device of the type described above, which removes plaque when operated.

It has been found according to the principles of the present invention that the elimination of tooth decay and dental plaque through the use of ultrasonic vibration in the pulsating jet stream can be further facilitated, both when used with the above-mentioned chemical solution to supplement the chemical action of the same as well as in the Oral hygiene effect of a pulsating stream of water.

Accordingly, another object of the present invention is to provide an improved apparatus of that described above Kind with means of imparting ultrasonic vibrations to the nozzle of the pulsating jet to both the material-removing effect of the pulsating liquid jet stream as well as the ability of the nozzle itself to remove it of material increase when brought into contact with the material that will be removed during the process target.

These and other objects of the present invention emerge from the subclaims:

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TO-SEREfCH

The invention is best understood with reference to the accompanying drawings, in which an embodiment is shown; show in it:

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Case 7 g.

Pig. 1 and 2 graphs to illustrate the time-pressure relationship the pulsating liquid streams continuously used in the relevant technology;

Fig. 3 ″ to 6 curves to illustrate the time-pressure relationship certain pulsating liquid streams that are being investigated during the Creation of the present invention;

7 and 8 are graphs of the time-pressure relationship of the pulsating liquid flows according to the present invention Invention;

9 is a schematic representation of an illustrative fiber their reaction when following the pulsed stream of liquid Fig. 1 to 6 is claimed or loaded;

Figures 10 and 11 are a schematic representation of a fiber illustrating its response after it has passed through the pulsed liquid streams of Figures 7 and 8 are correspondingly compressed;

Figure 12 is a side view of a pump mechanism with a variable Flow rate for generating the pulsating liquid flows according to FIGS. 7 and 8;

13 is a partial end view of a modified embodiment of an arrangement of a cam disk and a Cam followers;

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Pig. 14 is a partial front view of a cam disc or Disturbance curve in connection with a cam follower according to FIG. 13;

Pig. Figure 15 is a schematic view of a complete assembly of a creation and application device the .inventive improved pulsating fluid jet stream; and

Pig. 16 and 17 graphs to illustrate the time-pressure relationships of an undesirable nature due to too high a frequency and / or too low a capacity of the nozzle opening.

It is known to use a pulsating high velocity jet stream of liquid as a means of cleaning the mouth. However, until now it has not been possible to achieve a complete elimination of tooth decay. It has been found, and it is an object of the present invention, that tooth decay can be eliminated and teeth prepared for sealing when a solution of an N-haloamic acid having a pH between 10.5 and 11.5 as a pulsating liquid jet stream is one of Caries affected area is supplied; it can be used to remove plaque, but the chemical action only improves the treatment, while a chemical action is necessary to remove caries

According to the invention, it has been found that the shape or the course of the curve of the relationship between time and pressure

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the jet current pulsations a very important factor and is even more important than the frequency and the pressure. By selecting an appropriate time-pressure curve, a Period for complete relaxation of the attacked material introduced between the individual impulses.

The Pig. Figures 1 and 2 of the accompanying drawings show Figs Time-pressure curve of the method and the device according to the prior art, while FIGS. 3 to 6 further show such curves that are available. 7 and 8, however, show curves in which a zero pressure applied to the material for an extended period between each pulsation.

The pulsating shown in FIGS. 3f 4, 5 and 6 Jet currents are far less effective than the currents illustrated in Figures 7 and 8, the best being Results can be obtained with the current shown in FIG. While all shown in Figs. 1 to 6 pulsating Beam currents cause changes in the treated material in terms of voltage or load, do not allow it to relax even if the currents shown in Figs. 1, 3 and 4 are used, where the pressure continues to drop to zero with each cycle, since the time allowed at zero pressure is infinitely small. A complete relaxation of the material requires a certain period of time depending on its elasticity. on the other hand the time element in question is incomparably shorter in a period in which a voltage or load is lifted. As a means of showing the changes in the shape of a material subjected to compression under an applied pressure, an elastic

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Paser can be used. Those shown in Figs pulsating fluid jets generate vibrations or vibrations of a paser in the pig. 9, whereas the jet currents shown in FIG. 7 or 8 allow much larger vibrations due to the presence of an appropriate relaxation period, as in 10 and 11 shown. A similar phenomenon arises with solid elastic material, such as. B. plaque or tooth decay. These materials are therefore in depth effectively rinsed off, taking them in a proportionate way short period of time (seconds for plaque, minutes for dental caries), so these materials rather eliminated by erosion than by hydrodynamic erosion can be. Because the elastic properties of tooth materials differ from one case to another it is desirable to provide flexible facilities for setting the most efficient frequencies and to enable pressures independently of each other. The devices available to date do not allow independent ones Setting or adjusting frequencies and pressures, including setting the time element Do not allow tension and relaxation within a cycle.

Referring particularly to FIG. 12, this figure shows a device, which is indicated generally at 10, for generating a pulsating fluid jet stream, whereby the time and the pressure are changeable to the formation the characteristics of FIGS. 7 and 8 to enable. As shown, the device 10 has a fixed frame structure 12 to that of any conventional

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Can be of construction and has an appropriate shape to a Container or receptacle 14 for the supplied liquid and a power-driven pump mechanism Support, which is indicated generally at 16, to the amount of liquid contained within the container 14 to an outlet nozzle 18 which, as shown, is in the form of a hypodermic needle.

The illustrated pump mechanism 16 is preferably of the flexible diaphragm type, although it is understands that designs with a piston and cylinder and flexible bellows may also be used can. As shown, the pump mechanism includes a pump body 20 made of a suitable heat conductive material Material such as B. Metal or the like., On, the one Contains open ended pump chamber 22 arranged with its axis generally horizontal extends. The open end of the pump chamber 22 is closed by a flexible membrane 24 made of any Zwetkmässig elastic or flexible material, such as. B. rubber, plastic or the like. Is formed.

Within the central portion of the diaphragm 24, a plunger or piston rod 26 is embedded, which extends from the membrane extends axially outward. With the rod in a position next to the membrane 24 is the middle section a transverse head plate 28 firmly connected. The ends of the plate 28 are perforated to receive therein a pair of guide rods 30 in a guiding manner attached to the frame structure 12 in a parallel relationship to the piston rod 26

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are massively attached. The piston rod 26 and the diaphragm is as shown, by an appropriate conveyor such. B · a pair of spiral springs 32, in an outer limit position elastically urged, this spring the guide rod η and their ends are in contact with the transverse head plate 28 and the frame 12, respectively.

The movement - the piston rod 26 and the diaphragm 24 away from the limit position and in the direction of this position in successive work cycles is through an arrangement » obtained from a cam plate and a cam follower which, as shown, has a cam follower arm 34 which is pivotally connected at one end to the frame structure 12, as shown at 36, with its central portion is in contact with the other end of the piston rod. On the side of the central portion of the cam follower arm given over the piston rod 26, a cam disk 38 is attached to a shaft 40 which is connected to the drive shaft a control motor or electric motor 42 with variable speed is drivingly connected to the frame structure 12 is appropriately supported. The end of the cam follower arm opposite the pivot point 36 34 is arranged in a position in which it is in contact with an adjustment member 24, which is on an elongated Part 46 is conveniently arranged by thread, which is either firmly connected to the frame structure or forms part of the same. A retaining nut 48 is also threadedly provided on part 46 to hold the adjustment member to hold in any position of its adjustment along the part 46.

Figs. 13 and 14 show another arrangement of one Cam disc and a cam follower, which in place of the

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The arrangement described above can be used. As shown in FIGS. 13 and 14, the end of the piston rod is 26 forked as shown at 50 having a cam follower roller 52 rotatably supported therebetween. One Cam cup 54 is keyed on shaft 40 in such a way that it is axially movable with respect to the shaft. The cam disk 54 is provided with various cam control cam surfaces 56, 58 which are axially spaced apart from one another and 60 are formed in continuous contact, any of these surfaces with the cam follower roller 52 can be brought into engagement by adjusting the axial position of the cam disk 54 on the shaft 40. A such continuous contact cam drive has a low noise level and can be more durable than that intermittent drive according to Fig. 12 can be made.

It will be understood that the above two applications allow the operator to set the dwell time of each cycle to be set or adjusted. A fixed device or a device of fixed power however, may be desirable from the point of view of economy, so that by the present invention in their broadest aspects is taken into account.

In order to enable the cyclical movement of the pump mechanism 16 to increase the amount of liquid in the container 14 is supplied through the nozzle 18 as a pulsating jet stream is an inlet tube 62 with a shut-off valve provided therein 64 connected between the bottom of the container 14 and an inlet opening in the bottom of the pump chamber 22 is formed, wherein an outlet pipe 66 is formed between an outlet opening in the upper part of the pump chamber 22

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is, \ ind one end of a hollow handle portion 68 switched the opposite end of which has the hypotermatic needle nozzle 18; which extends from it.

In the case of the variable arrangement shown, the angular stroke of the cam follower arm 34 and 34 is accordingly adjusted by the adjustment of the stop or adjustment member 44 thus also the working stroke of the membrane 24 is adjusted or set. The period of time during which the cam 38 is connected to the lever arm 34, corresponds to the pulse of FIGS. 7 and 8, while the Period when the cam 38 is not in contact with the arm 34 is in the plant, the relaxation period after the Pig. 7 and 8 corresponds.

Another feature of this arrangement is that the pump is preferably provided with a shut-off valve 64 only in the inlet line. Nonetheless, shut-off valves can be used at the inlet and outlet. Another feature of the present arrangement is that the pressure or working stroke is carried out by the eccentric driven by the motor, whereas the springs generate the suction stroke. An eccentric or cam principle can be used in place of such threads, wherein the pump can be driven by a pair of cam eccentrics, one for the drive stroke and the other for the suction stroke, but the two only in part Turn on, arming the stroke and allowing the pump to be motionless for part of the revolution. One revolution must then represent a full cycle in any case.

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A complete device for generating and using or attaching a pulsating device according to the invention Fluid jet stream is in Pig. 15 shown. These The device consists of the device 10, as previously described, wherein an electrical heating element 70 and a thermostatic controller 72 embedded in the pump body 20 are to maintain the body temperature in the liquid. The motor 42 is powered by a foot and off switch 74 controlled. The foot switch 74 can optionally be equipped with a controller for the revolutions / minute be combined. The valves used here are preferably ball valves. The flexible pipe or hose can conveniently have an inside diameter of 3/16 to 1/4 inch and preferably reinforced with conveyor spirals be to avoid the absorption of the pulsation. The elasticity of the hose can cause some absorption so that the pulsating current tends to take the form shown in FIG. 8. Stroke frequency, pump capacity and nozzle orifice are desirably in equilibrium. Too high a frequency and / or capacity too small a nozzle opening can cause undesirable changes in the shape of a pulsating flow, See as Figs. 16 and 17 · The undesirable dental caries materials differ from one case to another in terms of their mechanical properties, with the following ranges found to be practical:

1. Large nozzle diameter hypodermic needles 33 to 10.

2. Frequency 100 - 1600 cycles / min.

3. Motionless period of the pump 50-955t during the Cycle.

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4. Flow rates 15 to 200 ml per minute.

5. Press 10 to 400 pounds / square inch maximum.

It was also found that a shown in FIG Beam current according to the following drawing figures can be applied to harder materials:

(a) Figure 16: A ^ B (maximum A = 50 $) for C ^ 1 / 3D

(maximum C = 33 $ of D)

(Td) Figure 17: A ^ B and C - 1 / 3D

It has been found to be practical to prefer water or a water solution with different pH values to use at body temperatures for treatment.

example 1 - Removal of deposits ** Pf / square inch 21 calibration gr, sharpen Flow - Liquid Teeth cleaning Motion nozzle 15 " pressure lot medium Time frequency loose iteration 21 " , 115 ** 80ml / min water 85 * 30988 33 " 65 120ml / min water 15 min 400 50 * 20 " 120 60ml / min water 12 min 150 90 * 20 " 300 75ml / min water 10 min 650 95 * 21 " 160 200ml / min water 14 min 1200 95 * 14 " 110 55ml / min Solution a 11 min 1600 92 * 115 55ml / min Solution b 12 min 600 90 * 2/0551 50 35ml / min Solution b 12 min 650 75 * - 14 - 8 min 550

Gases 7

Solution A NaOH HaGl Clycine

Water as a solution

obtained pH

0 _Λ 05 mol / l 0.05 "0.05"

11.1 "

Solution b

As above, with the addition of 0.008 mol NaClO per liter

The resulting pH 11.4

Example 2

A bad tooth prepared for sealing

Time frequency motion jet sharpen Flow Liquid- loose period pressure lot medium 5.5 250 8Of ₀ 20th **
120 65 Solution b 4th 650 90 pounds 21 90 47 Il 12th 150 5O # 109 60 40 It 11 800 95 ^ 21 95 48 It 14th 1200 95f ° 20th 135 57 It 2.5 500 8595 20th 85 30th ti 7th 500 9Ofo 23 90 25th ti 8.5 350 50 # 18th 70 35 It

WW

Pf / square inch

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During the device described so far and explained above Effective results were obtained, these results were improved by further improving, as shown in FIG Transducer 76 was incorporated into the device, which is attached to the handle 68 and electrically connected to an oscillator 78 is to generate a desired ultrasonic frequency.

The jet of liquid is fed to the teeth through the nozzle 18. The nozzle can be a tapered metal cylinder with a right surface for controlling the pulses · Disposable hyperdomatic needles can be used in the Nozzle can be used. The use of a needle as an orifice or outlet is desirable because it allows the Impulse is allowed to be directed to otherwise hard-to-reach areas in the mouth, the. Dentist then the tooth decay or plaque can scrape or scrape off when the liquid jet is applied, as the The nozzle can often be clogged or clogged with plaque or tartar or other material, the nozzles are easy interchangeable.

In a practical embodiment for the removal of tooth plaque and dental caries were maintained in the following working conditions:

1. Pressure - between 10 and 400 / square inch

2. Liquid flow rate or rate 20-150 ml / minute.

3. Nozzle diameter - 15 to 30 standard size of the hypodermic needles used.

4. Working temperature - 35 to 45 ° C, preferably Body rtempe ratür

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5. Pulse rate - 100 to 1600 pulses / minute.

6. Dwell Time - 50 to 90 # of the cycle.

The one used for the ultrasonic transducer attached to the nozzle Frequency is preferably between 5-75 KHz, preferably 20-25 KHz, with the energy output or the power output is between 5 and 50 watts. Ultrasonic vibrations increase the effectiveness of the Plussigkeitsjet and also improve the mechanical action of the nozzle. In working condition, the nozzle can be used to loosen Scraping off particles, the ultrasonic vibrations having been found to be very effective in this operation do·

According to the invention, which is "of.fenbart" in the applicant's parallel application file number 301 142, which ^{was filed under the title M} Electrolytic Treatment "on October 26, 1972, the entire disclosure of which is incorporated herein by reference electrolytically cleaved a solution of an alkali metal halogen or an alkaline earth metal halogen to thereby generate free halogen which then reacts to form hypohalite in the presence of a hydroxide ion. To form an N-halogen derivative, the starting solution should contain an appropriate amine compound or amino compounds. The hypohalite reacts to form an N-halogen derivative as soon as it has been formed in the solution.

The starting solution can contain one or more alkali metal or alkaline earth metal halogens.

Examples of suitable starting halogens are sodium chloride, sodium bromide, sodium iodide, lithium chloride,

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Lithium taomide, lithium iodide, potassium chloride, potassium bromide, Potassium iodide, rubidium or cesium chloride, potassium chloride, Calcium bromide, calcium iodide, strontium chloride, strontium bromide, Strontium iodide, barium chloride, barium bromide and barium iodide.

The resulting solution usually has an alkaline pH of 8 to 12 and preferably of 10.5 to 11.5 and especially 11 to 11.5. Me electrolysis is preferred carried out a solution 0.004-0.016-mole in N-halogenamine to build.

While it is not essential, it is preferred to have excess having non-halogenated amine present, d. H. in an amount up to 15 times as large as the halogenated amine and preferably 6 to 8 times more than the N-halogenated Amine on a mole basis.

As amine nitrogen compounds, either inorganic compounds, such as. B. sulfamic acid, or organic compounds used which have two to 11 carbon atoms included, e.g. B. glycene, sarcosine, alpha-aminiotiutyric acid, Taurine, 2-alcohol ethanol, N-acetylglyein, alanine, beta-alanine, Serine, phenylalanine, norvaline, leucine, isoleucine proline, Hydroxyproline, omega-aminundecanoic acid, glycylglycine, glycylglycylglycine (and other polypeptides), aspartic acid, glutamic acid, Glutamine, asparagine, valine, tyrosine, threonine, methionine, glutamine, tryptophan, histidine; Arghin, lysine, alpha amine butyric acid, Gamma-amine butyric acid, alpha-epsilondiamine pimelic acid, Ornithine, hydroxyllysine, anthranilic acid, p-aminbenzoic acid, Sulphonic acid, orthanilic acid, phenylsulphamic acid, amine propane sulphonstture, 2-amine ethanol — 2-amine propanol diethanolamine— ethylenediaminetetraacetic acid (EDTA) ,. Nitriltriacetic acid and Amine methanesulfonic acid

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Examples of Mona-N-halogen compounds include N-chloroglycine, N-bromoglycine, N-iodoglycine., N-chlorosarcosine, N-bromosarcosine, N-iodosarcosine, N-chloralphaamine isobutyric acid, N-chlorotaurine, N-brorataurine, N-iodotaurine _f N -Chlorethanolamine, N-chloro-N-acetylglycine, N-bromoethanolamine, N-iodethanolamine, N-iodine-N-acetylglycine, N-bromo-N-acetylglycine, N-chloralanine, N-chlorobetaalanine, N-bromobetaalanine, N-chloroserine , N-bromserine, N-iodoserine, N-chloro-N-phenylalanine, N-chlorisoleucine, N-chloronorvaline, N-chloroleucine, N-bromoleucine, N-iodineucine, N-chlorproline, N-bromoproline, N-iodoproline, N -Chlorhydroxyproline, N-chloromegaaminundecanoic acid, N-chloroaspaginic acid, N-bromoaspartic acid, N-chloroglutamic acid, N-iodoglutamic acid, N-chlorovaline, N-chlorotyrosine, N-bromotyrofinine, N-iodotyrosine, N-chlorothreonine, N-chloroglycine. " i-Chloroglycylglycylglycine, N-Chlorraethionine, N-Brommet] -ionine, N-Chlorotryptophan, N-Chlorhistidine, N-Chlorargeiiin, N-Chlorglutamine, N-Bromglutamine, N-Chlorlysine, N-GhI or gammaam inobutyric acid, N-chloralpha ^ tpsilon-diaminopimelic acid, N-chlorornithine, N-chlorohydroxylysine, N-chloranthraniic acid, N-chloro-p-aminbenzoic acid, N-chlorosulphamic acid, N-chloraminepropanesulphonic acid, N-aminomethanesulphonic acid, N-aminomethanesulphonic acid, N-aminomethanesulphonic acid, N-aminomethanesulphonic acid N-chloroethylene diamine tetraacetic acid.

The subsequent solutions can be prepared by the electrolytic process described above for forming the haloamines getting produced.

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Solution (mole in one liter of a water solution)

A. NaCl NaOH Amine compound 0.10 0.08 0.05 glycine B. KCl.
0.15 KOH
0.08 0.05 taurine C. LiBr
0.15 LiOH
0.08 0.05 clycine D. NaI
0.10, NaOH
0.12 0.10 sulfamins E. CaCl ₂
0.10 NaOH
0.07 0.05 glycine F. NaCl
0.10 NaOH
0.08 0.025 glycine
0.025 taurine

As noted in Applicant's copending application Serial No. 301 163, ^{filed on October 27, 1972, entitled "Dental Treatment * 1} , the entire disclosure of which is incorporated herein by reference, teeth are contacted with an N-haloamine which also contains a hydroxyl group, a sulfonic acid group, an N- <acyl group, for example an N-acetyl group or a carboxylic acid group.

The halogen has not determined an atomic weight of 35 to 127. If otherwise, in the present specification and claims, the term ^N-fl halogen "means" N-monohalo. ¹¹

Many of the N-halogen compounds are unstable and can are expediently prepared by an alkali metal or

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Alkaline earth metal hypohalin, preferably hypochlorite, is reacted with the amine compounds.

Examples of suitable hypohalites include sodium hypochlorite, potassium hypobromite, sodium hypoiodite, potassium hypoiodite, Potassium hypobromite, rubidium hypochlorite, cesium hypochlorite, galcium hypobroraite, strontium hypochlorite, and barium hypochlorite.

To react with the hypochlorite to form the N-halogen compounds according to the invention, any of the aminocarboxylic acids or aminosulfonic acids can be used, previously mentioned. The resulting N-halogen compounds, which are used according to the invention are those mentioned above, i.e. i.e., N-chloroglyoin ^ c. The in example Solution B used in 1 and 2 is an example of the formation of N-monochloroglycine in place or in situ from sodium hypochlorite and clycine.

Preferably N-haloamine carboxylic acids are used, for _e, amine alkanoic acids that are free of divalent sulfur of a heterocyclic ring, since, if the divalent sulfur atom or the heterocyclic ring is present, the N-HaIogenverbindung has a very short half-life.

The N-bromine and N-iodine compounds are the most effective, with them however, have shorter lifespans than the N-chlorine compounds, and therefore the N-chlorine compounds are usually used. The N-haloamine group is preferably attached directly to an aliphatic carbon atom, while compounds which have an unpleasant odor, preferably not be used.

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In Patent Application File No. 197,966 (Goldman et al.) Filed Nov. 11, 1971, the treatment is of teeth to eliminate tooth decay, to dissolve tartar or plaque and to prevent the Development of the build-up of lime through the use of sodium, potassium or calcium hypochlorite at a pH value from 9 to 11.5. In this patent application is discloses that non-toxic buffering agents can be used, mentioning that a preferred buffering agent is is a mixture of glycine, sodium chlorite and sodium hydroxide, in particular a mixture is shown from a 0.5 / ^ solution of sodium hypochlorite, 1 ^ -Glycine hypochlorite and a sufficient amount of sodium hydroxide exists to bring the pH to about 10 °. This * patent application 197 966 also discloses that a mixture of 1 ml of flavor, 98 ml of a buffer solution, 0.05 mole in glycine, 0.05 mole in sodium hydroxide and 0.05 mole in sodium chlorite and 1 ml of 5 $ NaOCl in 500 ml of water added and the product was made up to 1000 ml in addition with water. While Goldman et al were not aware they had performed N-chloroglycine in situ made this process, with N-chloroglycine being the active agent in their process. Goldman et al. also disclose the use of a jet of the solution, e.g. from a mechanical pump mechanism, z. B. a WATER PIC.

The nitrogen-containing parent compound is preferably used in excess to generate the N-halogen compound in situ to form from a hypohalite, for example the LIo! ratio of the nitrogen-containing parent compound to the

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Gases 7 ^<J

available X ⁺ (from the hypohalite) must be 1: 1 or greater and preferably in the range from 2: 1 to 15: 1 and in particular 7: 1. A mixture of nitrogen-containing compounds can be used.

The available active X concentration should preferably be between O, O1 # and θ / ο and in particular between 0.05 ^ and 1 $.

The N-haloamine solutions have a pH in the range from pH 8 to 12 and in particular in the range from pH 10.5 to 11.5 including and in particular 11 to 11.5 to use.

In order to maintain the preferred pH range, since hydrogen ions are generated during the cleavage of the H-halogen compound in an aqueous solution, it is desirable to add a buffer system to the solution. Such a buffering agent must be compatible with the N-halogen compound, ie it must not have any harmful effect on it and it must not be toxic. Borates and phosphates are examples of compatible salts for the formation of buffer systems, e.g. Na ₂ H PO ₄ can be used as the buffer system, since it can have the pH value above 10, although this buffer system has the pH value in other systems usually holds at a smaller value.

Of course, mixtures of N-halogen compounds can be used can be used. Unless otherwise specified, all parts and percentages are parts by weight and Weight percentage.

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The following formulations A-P show the formation of N-haloamides in situ, which are examples of the inventive effective represent.

Solutions used (the figures are in moles / liter of

Water solution)

NaOOl NaOh NaCl amine compound buffer pH value salt

A 0.008 0.0539 0.050 0.05 Glycine Na ₃ HPO ₄ 11.59

0.0025

B 0.008 0.0640 0.050 0.05 glycine Na ₃ B ₄ O ₇ 10.77

0.00125

C 0.008 0.0210 0.050 0.05 glycine Na ₃ B ₄ O ₇ 9.65

0.00125

D 0.008 0.0537 0.050 0.05 sulfamic- none 11.49

acid

no

E 0.008 0.0520 0.052 0.05 sulfamine- none 10.75

. acid

no

P 0.008 0.0548 0.050 0.05 taurine none 11.86

no

* The pH of all investigated solutions remained constant within 0.5 pH - value units for at least 1 hour.

Less preferably, N-dihaloamine compounds can be used in the present invention, such as e.g. B. N-dichloroglyein, N-dibromoglycine, N-diiodoglycine, N-dichlorosarcosine, N-dibromosarcosine, N-diiodosarcosine, N-dichioralphaaminisobutyric acid, N-dichlorotaurine, N-dibromotaurine, N-diiodotaurine, N-dichloroethanolamine, N-diiodethanolamine, N-dibromometaalanine, N-dichlorobetaalanine, N-dichloralanine, N-dichloro

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serine, N-dibroraserine, N-diiodserine, N-dichloroisoleucine, N-dichloronorvaline, N-dichlorleucine, N-dibromleucine, N-diiodleucine, N-dichloroproline, N-dibromoproline, N-diiodoproline, N-dichlorohydroxyproline, N-dichloromegaaminundecanoic acid, N-dichloraspartic acid, N-dibromaspartic acid, N-dichloroglutamic acid, N-diiodoglutamic acid, N-dichloro valine, N-dichlorotyrosine, N-Ditoromtyrosine, N-Diiodtyrosine, N-Dichiqrthreonine, N-dichloroglycylglycine, N-dichloroglycylglycylglycine, N-dichloromethionine, N-dibromomethionine, N-dichlorohistidine, N-Dichlorargenine, N-Dichlorglutamine, N-Ditroraoglutamine, N ^ dichlorolysine, N-dichlorogammaaminobutyric acid, N-dichlorornithine, N-dichlorohydroxylysine, N-dichloro-p-aminobenzoic acid, N-dichlorosulfamic acid, N-dichloraminepropanesulfonic acid, N-dichloroamine methanesulfonic acid.

It can thus be seen that the objectives of the present Invention have been fully and effectively achieved. It should be noted, however, that the above preferred specific Embodiment for the purpose of illustrating the functional and structural principles of the present invention have been described and illustrated using them Can experience modifications without departing from these principles. Therefore, the present invention includes all of them Modifications within the scope of protection of the attached Patent claims.

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Claims (1)

Claims Procedure for removing lime or limestone deposits and dirt, especially tartar, characterized in that on the deposits to be removed pulsating high-speed jet stream of liquid with an N-chloroglycine solution at a pH of 10.5 to 11.5 is directed, the pulsations being such that in each cycle the difference between those on the material applied highest pressure and a reduced pressure and the corresponding periods in which the material is highest Exposure to pressure and the lowered pressure causes the material to be mechanically tensioned and then completely relaxed will. 2. Process for removing lime or limestone deposits and dirt, in which the deposits with a brought into contact with an alkaline solution of an N-halogenamine , characterized in that said solution is applied to the deposits in the form of a pulsating liquid jet stream high speed is applied, the pulsations being such that in each cycle the difference between the highest and a reduced pressure exerted on the material and the corresponding periods, in which the material is under the highest and the lowered pressure, causes the material to be mechanical tensioned and then completely relaxed. 3. The method according to claim 2, characterized in that the beam current has a frequency in the order of magnitude of loo to 1600 cycles / minute and that the period of the her- - 27 - 309882/0551 ORIGINAL INSPECTED 27 'REQCREIOHT 2329729 applied pressure during each cycle in the order of magnitude is between 3o to 9o% of the total period of each cycle. U. The method according to claim 2, characterized in that the pulsating jet stream is an ultrasonic oscillation exposed before it is applied to the tooth. 5. Procedure for removing lime or limestone deposits, especially tartar, in which the deposits with an alkaline solution of an N-haloamine in Be brought into contact, which is selected from the group consisting of N-haloamines, which is a hydroxyl group, a sulfonic acid group, a carboxylic acid group and a N-acyl group, characterized in that said Solution is applied to the tooth in the form of a pulsating high-speed jet of liquid, the pulse ends being such that in each cycle the difference between the highest and a decreased Pressure exerted on the material and the corresponding periods in which the material is under the highest pressure and under the reduced pressure, cause the material to be mechanically tensioned and is then completely relaxed. 6. The method according to claim 5, characterized in that the beam current has a frequency of the order of magnitude from 10,000 to 1,600 cycles / minute and that the period of depressurization during each cycle is of the order of magnitude is between 3o to 9o% of the total period of each cycle. - 28 - 309882/0551 ORIGINAL INSPECTS _o ο ι SUBMITTED - / α - 2329723 7. The method according to claim 5, characterized in that the pulsating jet stream of an ultrasonic vibration is exposed to the application of the current to the deposits. 8. Procedure for removing lime or limestone deposits, especially tartar, in which the deposits come into contact with an alkaline solution of an N-haloamine are brought, characterized in that the solution on the deposits in the form of a pulsating · liquid jet stream high speed is applied, which is subjected to ultrasonic vibrations. 9. The method according to claim 8, characterized in that the liquid jet stream with a frequency in the Of the order of magnitude of 100 to 16oo cycles / minute and that each cycle has a dwell time of zero pressure in the Of the order of 3o to 9o% of the total period of each cycle. 10. Process for removing lime or limestone deposits, especially tartar, in which the deposits come into contact with an alkaline solution of an N-haloamine which is selected from the group consisting of N-haloamines, which is a hydroxyl group, a sulfonic acid group, a carboxylic acid group and a Contains N-acyl group, characterized in that the solution on the deposits in the form of a pulsating liquid jet stream high speed is applied, which is subjected to ultrasonic vibrations. 11. The method according to claim Io, characterized in that that the liquid jet stream with a frequency in the - 29 309882/05 51 - 29 - j NAO HOEREIOHTJ Order of magnitude from 100 to 160 cycles / MIN. pulsates and that each cycle has a dwell time of zero pressure in the order of magnitude of 3o to 9o% of the total period each cycle. 12. Procedure for removing lime or limestone deposits or dirt, including tartar, in which a pulsating jet of liquid hits the deposits high speed, characterized in that the pulsations are such that that in each cycle the difference between the highest and a reduced pressure applied to the material is exercised, and the corresponding periods in which the material is under the highest pressure and the reduced Pressure, cause the material to be mechanically tensioned and then completely relaxed. 13. The method according to claim 12, characterized in that the nature of the curve of the time pressure ratio each Cycle of pulsations is such that in each cycle there is a period of essentially zero application of pressure on the deposits * m. The method according to claim 12, characterized in that that the liquid used to remove the deposits is water. 15. The method according to claim 12, characterized in that the pulsating liquid jet stream before its application ultrasonic vibrations are applied to the deposits. - 3o - 309882/0551 _ 3O- j NAC HOEREtCHTI 16. A method for removing deposits, characterized in that a pulsating jet stream of a high-speed liquid is applied to the deposits is applied, which is subjected to an ultrasonic vibration. 17. The method according to claim 16, characterized in that the liquid jet stream having a pulse waveform is pulsed, which has a period of application of a maximum pressure in each cycle, the one period followed by sufficient relaxation to induce mechanical fatigue in the material associated with the jet stream is attacked. 18. The method according to claim 17, characterized in that the pulse waveform has an extended relaxation period of a reduced but positive pressure. 19. The method of claim 17, characterized in that the pulse waveform has an extended relaxation period from zero pressure. 2o _t method according to claim 16, characterized in that the liquid is neutral and acts on the deposits by abrasion and erosion. 21. The method according to claim 16, characterized in that the liquid is selected so that it is a chemical Has an effect on the deposits. - 31 - 30988 2/0551 _ 31 - 22. Device for removing dental deposits
or dirt or pressure pieces, characterized by a device for forming a jet, a liquid pump which has an outlet which is in communication with the device for forming a jet , and by means for repeatedly actuating the pump so that in each working cycle a period of application of a pressure supply is provided having a period of not applying a pressure supply follows. 23. The device according to claim 22, characterized in that the pump drive device is designed such that the length of the period of pressure supply during each
Cycle is changeable. - 32 - 309882/0551 Case 7 24. Device according to claim 22, characterized in that the pump drive means is adapted _r that the frequency of the duty cycle is variable. 25 · Device according to claim 22, characterized in that that the flow capacity of the device for forming of the ray is changeable. 26. The device according to claim 22 in combination with a container for the bulk supply of liquid, a check valve, which is a connection establishes a flexible pipe or hose between the container and an inlet of the pump, which establishes a connection between the pump outlet and the device for forming the jet and a flow control valve for the means for forming the jet. 27. The device according to claim 26, characterized in that that the device for actuating the pump has a drive, wherein a rotatable cam disk coupled to drive the prime mover and a cam follower is arranged with which the rotatable The cam disk comes into contact with a device that moves the cam follower with a movable one Element of the pump couples and a device with the cam follower is coupled to its return stroke to effect, and that an adjustable device for limiting the return stroke of the cam follower is provided is, and thus the change in the work - 32 309882/0551 Case 7 to allow stroke of the pump. 28. Device for removing deposits or fragments or dirt from teeth, marked by a device for forming a pulsed jet stream from a liquid, a Device for directing the jet stream from this liquid onto a tooth and through a device for imparting ultrasonic vibrations to said liquid jet stream. 29. Device of the type described above, characterized by a device through which a pump chamber is formed or delimited, which has a flexible membrane, which for movement between a first limit position in which said pump chamber has the maximum volume, and a second position in which said pump chamber is at its minimum volume has, by means of a power-driven cam disk and a cam follower, which are operatively connected to the membrane, to a cyclical Movement of the diaphragm resulting from a movement from said first position to said second position by a pressure stroke and a movement from said second position to said first position by a suction stroke with a frequency in the order of 100 to 1600 ^ klen / minute consists, said membrane in the first position during each cycle for a period on the order of 30 to - 3 3 309882/0551 2329723 Case 7 the total period of each cycle is maintained through a suction line through which a source of liquid is communicated with the pump chamber Check valve in the suction line, which controls the flow of the liquid through the line to the said Chamber allows, but blocks the flow in the opposite direction, through an outlet nozzle device and through a pressure line through which the pump channel with the outlet nozzle device is associated 39 · Device according to claim 29, characterized in that that the outlet nozzle device is a hypotermatic needle tube of the order of magnitude of 15 up to 30 calibration size, with a handle firmly connected to it. 31 · Device according to claim 30, characterized by a Device for generating ultrasonic vibrations in said handle. 32 · Device according to claim 29, characterized in that that the device for forming or delimiting the pump chamber is a body made of thermally conductive material and that a heating device in said body and a device for controlling the operation the heating device is provided to the liquid flowing through the pump chamber in a to maintain a predetermined temperature. 309882/0551 Case 7 33. Apparatus according to claim 29, characterized in that the suction line is connected to the pump chamber at its bottom section. 34. Provision according to claim 29, characterized in that the cam disk and the cam follower have a device "for changing the dwell time per cycle of the said membrane in the said first position . The patent law - 35 - 309882/0551