RU38582U1 - DEVICE FOR PHOTOPOLYMERIZATION OF DENTAL RESTORATION MATERIALS - Google Patents

Abstract

The utility model relates to medical equipment and can be used in dentistry for photopolymerization of dental restoration (filling) materials. The proposed utility model allows us to solve the problem of increasing the efficiency of the continuous and pulsed electromagnetic radiation of a diode when it is inserted into a fiber, which allows the material to be processed in hard-to-reach places (for example, in sealed channels), as well as to reduce the risk of infection during treatment of patients. The problem of the first embodiment of the utility model is solved by the fact that in the known device for photopolymerization of dental restoration materials (including a housing, power supplies and controls, a light source in the form of a semiconductor diode, a light focusing system and a light guide in the sheath, made in the form of a working nozzle, and also the interface node of the input end of the fiber with the LED) the interface is made in the form of an optical adapter located on the end of the housing, the input end of the fiber is equipped with a connector moreover, the device is equipped with a detachable optical connector, which ensures the fixation of the connector with the input end of the fiber on the housing. In the working position, the nozzle is connected to the device, and in the initial state it is pre-sterilized and placed in a sealed enclosure. The problem of the second embodiment of the utility model is solved by the fact that in the known device for photopolymerization of dental restoration materials (including a housing, power supplies and controls, a light source in the form of a semiconductor diode, a light focusing system and a light guide in the sheath, made in the form of a working nozzle, and also the interface unit of the input end of the fiber with the LED) the light source, the focusing system and the interface unit are separated from the housing in which the power and control unit and enes in a separate housing, which provides the functions of the handle for a working nozzle, and for connection to a detachable optical coupler is provided. In the working position, the nozzle is connected to the device, and in the initial state it is pre-sterilized and placed in a sealed enclosure.

Description

The utility model relates to medical equipment and can be used in dentistry for photopolymerization of dental restoration (filling) materials

A device is known for photopolymerization of dental restoration materials, including a housing, inside of which there is a radiation source in the form of a halogen lamp with a reflector, a cooling system for the lamp and a light guide fixed at the outlet of the housing (see RF patent No. 2116766, class A 61 C 5/04 , 1998). The device is also equipped with power supplies and a control system. The disadvantages of the device are its significant dimensions, the need to use a cooling system, as well as the relatively low efficiency of the beneficial use of light energy. In addition, the device is not equipped with technical means that would reduce the risk of infection.

A device is known for photopolymerization of dental restoration materials including a housing, inside of which there is a radiation source in the form of a semiconductor light-emitting or laser diode located at the outlet of the housing, a control unit and a power supply (see RF patent No. 2197194, class A 61 C 5/04 , 2000). In accordance with this invention, the power supply is either autonomous and arranged at the same time with the device body, or placed in the body of a dental unit and connected by an electric wire to the device body including an LED. The disadvantage of this device is the low specific density of radiation, which can be obtained on the polymerized material, which is due to the large angular divergence of the light from the diode installed directly at the outlet of the housing. In addition, the device is not equipped with technical means that would reduce the risk of infection.

A device is known for photopolymerization of dental restoration materials, comprising a predominantly cylindrical body, a radiation source in the form of a semiconductor light emitting diode, an optical system for focusing radiation of a diode (see PCT7NZ00 / 00065, class A 61 C 13/15, 1999). The batteries of the radiation source power supply and its control unit are also located inside the case. In accordance with the invention, the transmission of light radiation to the processed material is carried out either through the translucent head of the housing at an angle of 90 ° as a result of reflection from a mirror installed inside it, or through a curved fiber optic cable

diameter, the input end of which is located in the focus area of the optical system. This device is the closest to the claimed utility model. The disadvantage of this device is the low specific radiation density, which can be obtained on the polymerized material, due to the relatively large irradiation area. In addition, the device is not equipped with technical means that would allow the material to be processed in hard-to-reach places, and would also reduce the risk of infection during treatment of patients.

The proposed utility model allows us to solve the problem of increasing the efficiency of the useful use of the electromagnetic radiation of a diode when it is inserted into fibers of different diameters, which allows the material to be processed in hard-to-reach places (for example, in sealed channels), as well as to reduce the risk of infection during treatment of patients.

The problem of the first embodiment of the utility model is solved by the fact that in the known device for photopolymerization of dental restoration materials (including a housing, power supplies and controls, a light source in the form of a semiconductor diode, a light focusing system and a light guide made in the form of a working nozzle, and also a unit pairing the input end of the fiber with radiation from the LED) the interface is made in the form of an optical adapter located on the end of the housing, the input end of the fiber is equipped with a connector m, and the device is equipped with a means for fixing the connector with the adapter.

In the particular case of the first embodiment of the utility model, the working nozzle is pre-sterilized and placed in a sealed enclosure.

In another particular case of the first embodiment of the utility model, the light focusing system is made in the form of a condenser including an LED reflector and three lenses made of a material optically transparent in the radiation region of the LED with a refractive index of more than 1.4, for example, PMMA or TF-1 material .

In another particular case of the first embodiment of the utility model, the input end of the fiber is fixed in the connector with glue, and the connector is fixed in the optical adapter using a threaded connection or springs.

The problem of the second embodiment of the utility model is solved by the fact that in the known device for photopolymerization of dental restoration materials (including a housing, power supplies and controls, a light source in the form of a semiconductor diode, a light focusing system and a light guide in the sheath, made in the form of a working nozzle, and also the interface node of the input end of the fiber

with radiation from the LED), the light source, the focusing system, and the interface unit are separated from the housing in which the power and control unit is located and are made in a separate housing that provides handle functions for working with the working nozzle and for the connection with which it is equipped with a detachable optical connector.

In the particular case of the second version of the model, the light focusing system is made in the form of a condenser, which includes an LED reflector and three lenses made of a material optically transparent in the radiation region of the LED with a refractive index of more than 1.4, for example, PMMA or TF-1 material.

In another particular case of the second embodiment of the utility model, the working nozzle is pre-sterilized and placed in a sealed enclosure. The essence of the technical solution is illustrated in the figures. Figure 1 shows a General view of the device according to the first embodiment. Figure 2 shows a General view of the device according to the second embodiment. The device according to the first embodiment (see Fig. 1) consists of a housing 1, in which a power and control unit 2, a switch 3, an LED 5 are placed. The energy of the LED using a capacitor 7 is directed to the input end of the optical fiber 8 of the working nozzle 10. The input the end face of the working nozzle is made in the form of a detachable optical connector and mounted in the adapter 9 of the housing 1. The capacitor 7 is made in the form of three lenses 11. A part of the energy of the LED 5 extending beyond the aperture of the condenser 7 is directed into it by a reflector 6. The lenses 11 are made of material that is optically transparent in the field of LED radiation with a refractive index of more than 1.4, for example, from PMMA or TF-1 material. This embodiment of the condenser 7 can reduce its size, reduce aberration, increase the coefficient of radiation input into the optical fiber 8. The working nozzle 10 in the initial state is pre-sterilized and placed in a sealed sheath 12, which reduces the risk of infection during treatment of patients.

The device according to the second embodiment (see FIG. 2) consists of a housing 1, in which a power supply 2 is placed, and a switch 3. The LED 5 is placed in a separate housing 4 and is electrically connected to elements located in the housing 1. The energy of the LED using of the condenser 7 is directed to the input end of the optical fiber 8 of the working nozzle 10. The input end of the working nozzle is made in the form of a detachable optical connector and mounted in the adapter 9 of the housing 4. The capacitor 7 is made in the form of three lenses 11. A part of the energy of the LED 5 beyond ly aperture of the condenser 7, is sent to him reflector 6. The lenses 11 are made of optically transparent material in the region of the LED radiation with a refractive index

more than 1.4, for example, from PMMA or TF-1 material. The working nozzle 10 in the initial state is pre-sterilized and placed in a sealed shell 12, which reduces the risk of infection during treatment of patients

In another particular case of the second embodiment of the utility model, the light focusing system is made in the form of a condenser, including an LED reflector and three spherical lenses made of a material optically transparent in the radiation region of the LED with a refractive index of more than 1.4, for example, PMMA or TF- 1.

The proposed device embodiments make it possible to increase the efficiency of the continuous and pulsed electromagnetic radiation of the diode when it is inserted into optical fibers of various diameters, which allows the material to be processed in hard-to-reach places (for example, in sealed channels), as well as to reduce the risk of infection during treatment of patients. In addition, the proposed solution can significantly reduce the cost of the device for photopolymerization of dental restoration materials in comparison with similar laser and lamp devices, as well as significantly reduce the size and weight.

Claims (5)

1. A device for photopolymerization of dental restoration materials, including a housing, power and control units, a light source in the form of a semiconductor diode, a light focusing system and an optical fiber in the shell, made in the form of a working nozzle, as well as the interface unit of the input end of the optical fiber with an LED, characterized in that the interface is made in the form of an optical adapter located on the end of the housing, and a removable nozzle, the input end of which is equipped with a connector, which in the working position is connected to the device property, and in the initial state it is previously sterilized and placed in an airtight shell. 2. The device according to claim 1, characterized in that the light focusing system is made in the form of a condenser including a spherical mirror of the LED and three lenses made of a material optically transparent in the radiation region of the LED with a refractive index of more than 1.4, for example, PMMA material or TF-1. 3. The device according to claim 1, characterized in that the input end of the fiber is fixed in the connector with glue, and the connector is fixed in the optical adapter using a threaded connection or springs. 4. A device for photopolymerization of dental restoration materials, including a housing, power and control units, a light source in the form of a semiconductor diode, a light focusing system and an optical fiber in the shell, made in the form of a working nozzle, as well as an interface unit for the input end of the optical fiber with an LED, characterized in that the light source, the focusing system and the interface node are separated from the housing, which houses the power supply and control unit and is made in a separate housing that provides the functions of the handles for a working nozzle, which in the operating position is connected to the device, and in the initial state preliminarily sterilized and placed in a sealed envelope. 5. The device according to claim 4, characterized in that the light focusing system is made in the form of a condenser including a spherical mirror of the LED and three lenses made of a material optically transparent in the radiation region of the LED with a refractive index of more than 1.4, for example, PMMA material or TF-1.