RU2055542C1 - Device for cutting metal tooth crowns - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: metal tooth crown is subjected to anode dissolving with the help of dielectric cap fitted on the tooth. Cap inside accommodates flexible member resting on cap end face and crown surface. Located on cap outside is dielectric stop connected with electrode-cathode by means of rigid rods and with cap end face with the aid of flexible members. When jawbones are compressed, flexible members are also compressed, electrodes are connected with current source. Current drop detected by control instrument is indicative on completion of cutting the metal crown. EFFECT: higher efficiency of treatment, prevention of injury of mucous membrane of oral cavity, treatment of subgingiva crown part, reduced wear of stomatologic tools and facilities, localization of the zone of crown cutting, decreased current consumption and prevented short-circuits. 2 cl, 3 dwg

Description

 The invention relates to medicine, namely dentistry, and can be used to remove metal crowns from teeth.

 Known devices for removing crowns with wheel-shaped burs, discs or special forceps.

 The disadvantages of the devices include the impossibility of dissecting metal crowns in the cervical region, the likelihood of injury to the gums, mucous membranes of the cheeks, lips, difficult working conditions of the doctor when working with molars, a lot of dullness and wear on the instruments, considerable effort on the part of the doctor and negative emotions in the patient.

 Also known devices for non-contact anodic dissolution of metals, where it is shown that the process proceeds without tool wear.

 The disadvantages of the known devices include the inability to localize the processing zone for various parts; the need for high currents.

 The proposed device eliminates these disadvantages and is aimed at improving the effectiveness of treatment, preventing injury to the oral mucosa, treating the subgingival part of the crown, reducing wear of dental instruments, localizing the treatment area, reducing the input current, eliminating the possibility of short circuits.

 The goal is achieved as follows. Inside the dielectric cap, on the side of the end face, with an elasticity of not more than half the force of pressing the teeth during chewing, an elastic element resting on one end of the cap and on the other chewing surface of the crown is installed; outside, a dielectric stop is installed at the end of the cap, connected to the cathode electrode by rigid rods and to the end of the cap by elastic elements with a total elasticity greater than the elasticity of the first elastic element, but not more than the pressure of the teeth when chewing, and the ends of the cathode electrode have bevels on the outer surface side covered with an elastic dielectric, in addition, the electrode-cathode is coated with a constant section insulation on all sides except the opposite crown, and the guides on the inner surface of the cap are made in the shape of grooves with bevels on the sides opposite the grooves.

 Figure 1 shows the proposed device; FIG. 2, section AA in FIG. 1; figure 3 circuit supply current and electrolyte.

 The device includes a standard dental cap 1, selected according to the shape of the tooth. An electrode-anode 2 is installed in the cap wall in the form of a flexible clip made of a material resistant to anodic dissolution in the medium of the used electrolyte, for example, a titanium stored alloy. On the outside of the cap, pipelines are installed for supplying 3 and draining 4 liquids from the treatment zone. Inside the cap there is an electrode-cathode 5 of a metal resistant to dissolution, coated on the outside with an insulation layer 6, except for side 7, the opposite crown. Coating on the side of the cap is also optional. To move the electrode 5 made vertical grooves 8 of hardening plastic. At the ends of the electrode 5, the outer surface is covered with an elastic material, for example fluoroplastic. On the chewing surface side, the electrode 5 is rigidly connected to metal rods 9, to which a dielectric stop 10 is attached at other ends. Elastic elements, for example springs 11, are mounted on the rods. The elasticity of these elements must be not less than the elasticity of element 12 between the crown and the inner surface of cap 1 The elasticity of the element 12 should be sufficient to return to the original position of the cap 1 after pressing from the outside. Given the normal chewing force of 300-400 N, it is possible to set the elasticity of element 12 in the range of 50-120 N, and the total elasticity of elements 11 to 150 to 300 N. With these parameters, it is possible to guarantee the cap can be moved along the crown when the crown is separated using less current, what would be required if the cap was fixed, and at the end of the process, under the influence of the pressure of the antagonist teeth on the stop 10, the elastic elements 11 will begin to compress 11. A conductor 13 is connected to one of the rods 9.

 The device operates as follows.

 The assembled device is connected to a container 14 with an electrolyte, for example, a 12% aqueous solution of sodium chloride, and to a suction device 15, for example, a low-pressure vacuum pump. The electrodes 2 and 13 are connected to a current source 16 with current control devices 17. In this case, the connecting sections of the electrodes 2 and 3 are made non-interchangeable, for example with different thread diameters. A layer of quick-hardening mixture 18 is applied on the inner surface of the cap from the open side between the grooves, for example, wax, paraffin, put the cap 1 on the crown 19 until the element 12 stops against the chewing surface. Turn on the current, the suction of the electrolyte and record the current value of the instrument 17. Due to the gap between the working surface 7 of the electrode 5 and the crown 19, it is possible to suck saliva and air into the cavity between the cap and the crown. This does not violate the process of cutting the crown, as saliva is conductive, and air improves the localization of the process. Watch the cutting process on the instrument 17. When the current decreases, press the teeth on the stop 10 until the current value is restored. After ultimate compression of the element 12, the elements 11 begin to compress. In this case, the cap 1 does not move, but the electrode-cathode 5 moves in the grooves 8. The ends of the electrode 5 covered with elastic material enter between the gum 20 and the crown 19 to the depth of the gingival pocket. The process of separation of the crown 19 continues due to the saliva drawn through the gap between the surface 7 of the electrode 5 and the crown 19. The drop in current on the device 17 indicates the end of the process of cutting the crown. The current is turned off, the electrolyte is sucked off, the cap is removed, the mains are disconnected, the device is sterilized.

 The proposed device allows to increase the effectiveness of treatment, eliminates the likelihood of injury to the mucous membrane of the oral cavity, reduces wear of dental instruments, localizes the treatment area, eliminates the possibility of a short circuit.

Claims (2)

 1. DEVICE FOR CUTTING METAL CROWNS, including a dielectric cap, electrodes isolated from each other, characterized in that an elastic element with elasticity of not more than half the force of pressing the teeth during chewing and resting on one end of the cap is installed inside the cap from the end face; and on the other, on the chewing surface of the crown, on the outside of the cap end there is a dielectric stop connected to the cathode electrode by rigid rods and to the cap end - by elastic elements with total elastic Strongly elasticity over the first elastic member, but not more than the tread force of the teeth when chewed, and the ends of the cathode electrode-side bevels have an outer surface covered with an elastic dielectric.  2. The device according to p. 1, characterized in that the side sections, except the opposite crown, are covered with a layer of insulation of constant cross section, and the guides on the inner surface of the cap are made in the form of grooves with bevels on the sides opposite to the grooves.

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