KR20120027601A - Aqua thermal light pressure indirect composite restorative system with led-lamp and control method thereof - Google Patents

Abstract

The present invention relates to a polymerization apparatus, and more particularly, to a two-step polymerization process including a light polymerization process to form the whole form, a light heat polymerization process to make the pores more rigid, and the polymerization process is performed under high pressure. The present invention relates to an LED polymerization apparatus that does not generate bubbles in the pores so that high-quality pores are produced.
Such a feature of the present invention is a polymerization cup insertion hole into which the light polymerization cup or heat polymerization cup into which the pores are contained is formed, and the light polymerization cup or the heat polymerization cup is inserted into the upper portion of the polymerization cup insertion hole while sliding. Bonded polymer slide fastening portion is provided, the upper edge of the light polymerization cup or heat polymerization cup protrudes in the shape of a blade is provided with a rail guide is provided for sliding coupling with the polymer slide fastening portion, the light polymerization cup in the polymer slide fastening portion Alternatively, the slide guide is inserted into the rail guide of the heat polymerization cup and a slot having a cross-sectional shape of a 'c'-shaped groove is formed, and the upper portion of the light polymerization cup or the heat polymerization cup is supported by the polymerization slide fastening portion of the slide hole portion. Characterized in that it is provided.

Description

LED polymerization apparatus and its control method {AQUA THERMAL LIGHT PRESSURE INDIRECT COMPOSITE RESTORATIVE SYSTEM WITH LED-LAMP AND CONTROL METHOD THEREOF}

The present invention relates to a polymerization apparatus, and more particularly, a two-step polymerization process in which the entire form of the pores is first formed through the light polymerization process, and the shaped pores are made solid by the light heat polymerization process. The present invention relates to an LED polymerization apparatus that prevents bubbles from forming in the pores, fastens and separates a polymerization cup containing pores in a polymerization process, and maintains an airtight state.

BACKGROUND OF THE INVENTION In general, various techniques are used to fabricate restorations or dentures for repairing a portion of a damaged tooth in dental treatment. In particular, the polymerization method is used as a method for producing the final restoration or denture during the production of the restoration or denture.

The polymerization method other than the prior art includes a technique using only an oxygen inhibiting gel, a nitrogen gas, and a photopolymerization method of halogen lamps in the air by photopolymerization of halogen lamps in the air for restorations or dentures. There are technologies that allow more than 8 hours to progress, and technologies that only illuminate the halogen lamp in a vacuum.

However, according to the prior art, since the polymerization process takes a long time, not only the efficiency is lowered to produce a single pore, but also the power cost is excessively consumed because most of the halogen lamps are used.

In particular, when the halogen lamp is used, high heat is generated around the halogen lamp to provide a separate cooling configuration, and the halogen lamp peripheral members may be damaged due to overheating.

In addition, according to the conventional technology, since the pores are not manufactured in an optimal state, a large amount of bubbles are generated inside the pores manufactured by the prior art as shown in FIG. 25. If it is not hard and is treated with dentures and the patient chews hard during use, the dentures may be damaged immediately.

In addition, when many bubbles are generated in the pores manufactured according to the prior art, the color becomes poor, the appearance is not smooth, and in particular, each layer of the pores composed of a plurality of layers becomes poor.

The present invention for solving the problems described above, to form a smooth and desired appearance by first forming the entire form of the pores through the light polymerization process, and then the form of the pores having a form by the light heat polymerization process is a solid state The two-stage polymerization process is performed, and furthermore, the high-quality pores and dentures are manufactured by preventing the formation of unnecessary bubbles or voids in the pores by performing the high pressure state during the light polymerization process and the light heat polymerization process. The purpose is to make sure.

The light polymerization process is about 5 minutes and the light heat polymerization process is about 30 minutes, so that the overall time required to manufacture a single pore is shortened to improve production capacity.

In addition, since the LED lamp is used in the LED polymerization apparatus to perform the polymerization process, the LED lamp of the optimum frequency band suitable for the polymerization of the porous material can be applied. It is possible to make good, not to waste unnecessary power, as in the conventional halogen lamp, and also to minimize the cooling configuration due to overheating, and also to prevent damage due to overheating the LED lamp member.

Furthermore, in the LED polymerization apparatus, the polymerization cup containing the pores so that the polymerization reaction is carried out is distinguished from the light polymerization cup, the heat polymerization cup and the members thereof, so that the light polymerization process and the light heat polymerization process are optimal. By doing so, the highest quality pores are produced.

And by the shape of the slide slot hole of the polymerization slide fastening portion to which the light polymerization cup and the heat polymerization cup are combined and other air sealing tube members, the polymerization operation can be easily operated by one-touch, making it convenient to use each member. By self-diagnosing the operation by itself, the best quality pores are produced by optimally maintaining polymerization conditions that can produce subtle differences.

The present invention for achieving the above object, the pore (11) is contained in the LED polymerization apparatus 10 is provided with a light polymerization cup 20 or heat polymerization cup 30 is combined to achieve a polymerization action. In the LED polymerization apparatus 10, a polymerization cup insertion hole 12 into which the light polymerization cup 20 or the heat polymerization cup 30 is inserted is formed, and an inner upper side of the polymerization cup insertion hole 12 is formed. As the light polymerization cup 20 or the heat polymerization cup 30 is provided with a sliding slide coupling portion 40 is inserted into the sliding coupling, the upper portion of the light polymerization cup 20 or the heat polymerization cup 30 Rail guides (21) and (31) are formed at the edges to protrude in a wing shape and slide-bond with the polymer slide fastening portion (40). Rail guides 21 and 31 of the polymerization cup 30 are inserted A slide long hole 41 having a groove having a shape of a 'c' shape is formed, and the light polymerization cup 20 or the heat polymerization cup 30 is formed by the polymerization slide fastening portion 40 of the slide long hole 41. An LED polymerization apparatus is provided, characterized in that the upper portion is supported.

The LED lamp 42 is coupled to the upper side of the polymer slide fastening portion 40 so that the LED light emitted from the LED lamp 42 is illuminated by the light-transmitting portion 43 in the center of the polymer slide fastening portion 40. The airtight tube 45 is provided so as to be reflected on the pore 11 positioned inside the polymerization cup 20 or the heat polymerization cup 30, and around the light-transmitting portion 43 of the polymerization slide fastening portion 40. Is provided so that the upper portion of the light polymerization cup 20 or the heat polymerization cup 30 and the lower portion of the polymerization slide fastening portion 40 by the expansion of the air sealing tube 45, the light polymerization cup 20 or An air pressurizing unit 46 is provided to apply high-pressure air pressure into the heat polymerization cup 30, and the sample polymerization cups 22 and 32 of the light polymerization cup 20 or the heat polymerization cup 30 are provided. Tungsten is included and provided, and the polymer slide coupling part 40 may include tungsten.

In addition, the inside of the polymerization cup insertion hole 12 is connected to the connectors 23 and 33 of the light polymerization cup 20 or the heat polymerization cup 30 to be transferred to the light polymerization cup 20 or the heat polymerization cup 30. A connector power supply terminal 13 for transmitting a signal is provided, and the light polymerization cup 20 or the heat polymerization cup 30 surrounds the sample polymerization cups 22 and 32 in which the pores 11 are contained. Polymerization cases 24 and 34 having handles 241 and 341 coupled to the front are provided, and a bottom portion of the heat polymerization cup 30 is provided with a heater heater 342 heated by electricity. It is provided so that the heating action for the, the inner bottom of the polymerization cup insertion hole 12 is provided with a cooling fan 14 for cooling the light polymerization cup 20 or the heat polymerization cup 30, the light polymerization Lighter to contain the pore 11 is contained in the interior of the cup 20, the reflecting beads 251 below the pore 11 The ball cup 25 may be provided, and the heat pore bond 35 in which the pores 11 contained in the heat polymerization cup 30 are contained may be provided.

In addition, the LED polymerization apparatus 10 is controlled to perform the polymerization process for the pores 11 contained in the light polymerization cup 20 or the heat polymerization cup 30, and the detection received from the temperature sensor 62 When it is determined that the signal is overheated, the cooling fan 14 is controlled to operate, and the light polymerization cup 20 or the heat polymerization cup 30 is coupled to the signal of the polymerization cup insertion hole 12, the cup recognition switch ( 15) is provided with a polymerizer control unit 60 to receive from, and receives the control signal of the polymerizer control unit 60 to cause the LED lamp 42 to emit light to shine the LED light on the pores 11 An LED operating unit 61 is provided, and the air sealing tube 45 is expanded by the control of the polymerizer control unit 60 and compressed air is supplied into the light polymerization cup 20 or the heat polymerization cup 30. It is provided with an air operation unit 63, and the electric power to the LED polymerization apparatus 10 The heater heating unit 342 by supplying electricity to the heater heating unit 342 of the heat polymerization cup 30 through the connector power supply terminal 13 and the connector 33 in response to the control signal of the polymerizer control unit 60. ) May be provided with a power supply 64 to be heated.

The present invention provides a control method for controlling the LED polymerization apparatus, wherein the power is supplied to the LED polymerization apparatus 10 by the operation of the power switch 71 to prepare a polymerization operation (S01); The rail guides 21 and 31 of the light polymerization cup 20 or the heat polymerization cup 30 are slide-bonded along the slide holes 41 of the polymerization slide fastening portion 40 to contain the light polymerization cups containing pores. 20) or a polymerization cup position step (S02) of detecting that the heat polymerization cup 30 is located in the polymerization cup insertion hole 12 and transmitting a detection signal to the polymerization controller control unit 60 by detecting it in the cup recognition switch 15; After the polymerization cup positioning step (S02), the air sealing tube 45 under the polymerization slide fastening portion 40 is expanded by the control of the polymerization controller control part 60 to polymerize the fastening slide fastening portion 40 and the light polymerization cup 20. Or a polymerization space sealing step (S03) to seal the polymerization space 401 formed inside the heat polymerization cup 30; By the polymerization space sealing step (S03), the polymerization slide fastening portion 40 and the polymerization space 401 inside the light polymerization cup 20 or the heat polymerization cup 30 is compressed into the polymerization space 401 in a sealed state. Compressed air pressure step (S04) so that the air is injected so that the pressing process for the pore 11 is made; The LED lamp 42 is operated in the state in which the compressed air is injected into the polymerization space 401 by the compressed air pressure step S04 so that the LED light is reflected on the pores 11 in the polymerization space 401. Writing polymerization step (S05) to make the photopolymerization process for the pores (11); A lighting termination step (S06) for terminating the photopolymerization process by dimming the LED light for the pores after the lighting polymerization step (S05); Compressed air discharge step (S08) to discharge the compressed air that was injected into the polymerization space 401 to end the pressurization process for the pore (11); The air sealing tube 45 is expanded between the polymerization slide fastening portion 40 and the light polymerization cup 20 or the heat polymerization cup 30 to maintain airtightness, such that the light polymerization cup 20 or the heat polymerization cup ( 30 is a polymerization termination step (S09) is provided to be separated from the polymerization slide fastening portion 40 and the polymerization cup insertion hole 12 to terminate the polymerization process for the pores of the polymerization space (401). Provided is a control method of an LED polymerization apparatus.

Accordingly, the polymerization operation preparation step (S01) is to perform the operation preparation process including the buzzer sound generation process, the cooling fan check process, the display LED flashing check process, the display window flashing check process, the polymerization in the polymerization cup position step (S02) When the light polymerization cup 20 is positioned in the cup insertion space 12, the polymerization controller control unit 60 determines that the light polymerization cup 20 is combined, and the polymerization space sealing step (S03) and the compressed air pressure step are performed. (S04), the light polymerization step (S05), the writing end step (S06), the compressed air discharge step (S08), the polymerization end step (S09) to be carried out sequentially to the light polymerization process is carried out, the polymerization cup position step When the heat polymerization cup 30 is positioned in the polymerization cup insertion space 12 in step S02, the polymerization controller control unit 60 determines that the heat polymerization cup 30 is combined, and the polymerization space sealing step S03. , Compressed air pressure step (S04), writing polymerization step (S05), finish writing In addition to allowing the system (S06), the compressed air discharge step (S08), and the polymerization termination step (S09) to be sequentially performed, the light heat polymerization process in which the heating polymerization step (S07) is further performed after the lighting termination step (S06) is performed. In the heating polymerization step (S07), the electric power is supplied through the connector power supply terminal 13 and the connector 33 of the heat polymerization cup 30 from the power supply unit 64 according to the control signal of the polymerization controller control unit 60. Is supplied, the heater heating portion 342 of the bottom of the heat polymerization cup 30 is heated to operate the sample polymerization cup 32 of the heat polymerization cup 30 is heated to the light heat polymerization process for the pores 11 It may be provided to be made.

The present invention constituted as described above is to form a smooth and desired appearance by first forming the entire form of the pore through the light polymerization process, and then to form a pore shaped in the solid state by the light heat polymerization process. The polymerization process of the step is carried out, and furthermore, the light polymerization process and the light heat polymerization process are carried out at high pressure, thereby producing excellent pores and dentures by producing unnecessary pores and dentures in the pores. There is.

In addition, the light polymerization process is performed for about 5 minutes, and the light heat polymerization process is made for about 30 minutes, so as to shorten the time required to manufacture a single pores as a whole to improve the production capacity.

In addition, since the LED lamp is used in the LED polymerization apparatus to perform the polymerization process, the LED lamp of the optimum frequency band suitable for the polymerization of the porous material can be applied. It is possible to make good, not to waste unnecessary power, as in the conventional halogen lamp, and also to minimize the cooling configuration due to overheating, and also to prevent damage due to overheating the LED lamp member.

Furthermore, in the LED polymerization apparatus, the polymerization cup containing the pores so that the polymerization reaction is carried out is distinguished from the light polymerization cup, the heat polymerization cup and the members thereof, so that the light polymerization process and the light heat polymerization process are optimal. By doing so, the highest quality pores are produced.

And by the shape of the slide slot hole of the polymerization slide fastening portion to which the light polymerization cup and the heat polymerization cup are combined and other air sealing tube members, the polymerization operation can be easily operated by one-touch, making it convenient to use each member. By self-diagnosing the operation by itself, the best quality pores are produced by optimally maintaining polymerization conditions that can produce subtle differences.

1 is a perspective view of the LED polymerization apparatus according to the present invention.
Figure 2 is a schematic illustration of the polymerization slide fastening portion of the LED polymerization apparatus according to the present invention.
3 is a rear perspective view of the LED polymerization apparatus according to the present invention.
Figure 4 is a perspective view of the heat polymerization cup of the LED polymerization apparatus according to the present invention.
5 is a view illustrating the operation before the light polymerization cup is inserted for the LED polymerization apparatus according to the present invention.
6 is an exemplary view of the operation before the heat polymerization cup is inserted for the LED polymerization apparatus according to the present invention.
7 is an exemplary view illustrating the operation of the polymerization cup is coupled to the LED polymerization apparatus according to the present invention.
8 is a front view of the LED polymerization apparatus according to the present invention.
Figure 9 is an illustration of the coupling of the polymerization slide fastening portion and the light polymerization cup of the LED polymerization apparatus according to the present invention.
Figure 10 is an illustration of the coupling of the polymerization slide fastening portion and the heat polymerization cup of the LED polymerization apparatus according to the present invention.
11 is an exemplary cross-sectional view of the light transmitting portion of the polymer slide fastening portion in the LED polymerization apparatus according to the present invention.
12 is a perspective view of a state in which an installation hole of a main fan and a power connector is formed as a bottom portion of a polymerization cup insertion hole base of an LED polymerization apparatus according to the present invention;
13 is a plan view of the polymerization slide fastening portion of the LED polymerization apparatus according to the present invention.
Figure 14 is a bottom view of the heater heating unit is installed in the heat polymerization cup of the LED polymerization apparatus according to the present invention.
15 is a plan view of a reflector of the LED polymerization apparatus according to the present invention.
Figure 16 is a side view of the reflector of the LED polymerization apparatus according to the present invention.
Figure 17 is a bottom view of the air sealing tube of the LED polymerization apparatus according to the present invention.
18 is a cross-sectional view taken along the line AA of Figure 17, a detailed cutaway view of the air-sealing tube of the LED polymerization apparatus according to the present invention.
19 is a cross-sectional view taken along the line BB of Figure 17, a detailed cutaway view of the air sealing tube and the inlet of the LED polymerization apparatus according to the present invention.
20 is a configuration diagram for a control configuration of the LED polymerization apparatus according to the present invention.
21 is a flowchart illustrating a light polymerization process in the LED polymerization apparatus according to the present invention.
22 is a flowchart illustrating a light heat polymerization process in the LED polymerization apparatus according to the present invention.
23 is an exemplary graph of a sequence according to a light polymerization process in the LED polymerization apparatus according to the present invention.
24 is an exemplary graph of a sequence according to the light heat polymerization process in the LED polymerization apparatus according to the present invention.
25 is an exemplary cross-sectional view of a pore manufactured by the prior art.
26 is an exemplary cross-sectional view of the pores produced by the LED polymerization apparatus according to the present invention.
27 to 30 are exemplary flow pictures of a dental treatment process by which the pores manufactured by the LED polymerization apparatus according to the present invention is applied, Figure 27 is a picture of the teeth in a washed state for treatment before the procedure , Figure 28 is an illustration of the pores produced by the LED polymerization apparatus according to the present invention in accordance with the tooth to be treated, Figure 29 is a target tooth to be bonded to the pores produced by the LED polymerization apparatus according to the present invention It is an exemplary photograph of the state in which the adhesive is applied to, Figure 30 is an exemplary photograph of the teeth in the state that the pores manufactured by the LED polymerization apparatus according to the present invention is combined.
31 is a light characteristic graph according to the LED light used in the LED polymerization apparatus according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

That is, the LED polymerization apparatus 10 according to the present invention is a state in which the light polymerization cup 20 or the heat polymerization cup 30 in which the pores 11 are contained therein, as shown in FIGS. In the LED polymerization apparatus 10 for allowing the light light is shining in the state in which the pressure is applied to the pores 11 so that the light polymerization process is performed, and the light heating polymerization process is sequentially performed by heating the heating under the pressure. It is about.

In particular, in the conventional polymerizer, most of the light source uses a halogen lamp that consumes a lot of power, but in the present invention, the LED lamp is used to reduce the power consumption and to improve the optical characteristics. In other words, since most halogen lamps are illuminated as a whole, and the lamp members and the surroundings are heated to a high temperature, the structure for heat dissipation is complicated, and there is a difficulty in manufacturing. In addition, it consumes energy for heat dissipation as well as power consumption due to lamp operation. There was also a drawback to take.

However, in the present invention, since the LED light is used, the heat generation is less, so that the heat dissipation configuration can be minimized, and thus the power consumption is reduced.

In addition, when the conventional halogen lamp is applied as shown in FIG. 31, the wavelength range is wide, and thus, a region that is not actually required for polymerization is covered, which causes energy consumption. However, when the LED light source is used as in the present invention, Since the LED of the required frequency band is applied, while reducing unnecessary energy consumption, only the light source required for polymerization is reflected on the pore 11, so that the polymerization characteristics are more excellent. Therefore, not only the light polymerization process can be shortened, but also the monolayer formation of the pores as shown in FIG. 26 will have a cleanly polymerized state without voids.

Looking at the specific configuration for the LED polymerization apparatus 10 according to the present invention provided as described above are as follows.

First of all, the LED polymerization apparatus 10, the light polymerization cup 20, the heat polymerization cup 30 is coupled to the front as a whole, while forming an enclosure shape, the upper check the operating state of the LED polymerization apparatus 10 A display panel 101 is provided.

At the rear, there will be a power supply, air supply and LED heatsink fan. In addition, the inside of the LED polymerization apparatus 10 will include a variety of operating members, including the electronic circuit portion such as the polymerizer control unit 60 to operate.

This is provided with a light polymerization cup 20 and a heat polymerization cup 30 so that the pores 11 to be subjected to the polymerization process, the light polymerization cup 20 or the heat polymerization cup 30 is inserted The polymerization cup insertion hole 12 is formed in the LED polymerization apparatus 10.

In addition, the inside of the polymerization cup insertion hole 12 is provided with a polymerization slide fastening portion 40 which is inserted and coupled while the light polymerization cup 20 or the heat polymerization cup 30 is sliding.

In order to facilitate the coupling to the polymerization slide fastening portion 40, the upper edge of the light polymerization cup 20 or the heat polymerization cup 30 is protruded in the shape of a blade and slide coupling with the polymerization slide fastening portion 40 Rail guides 21 and 31 provided to be formed.

The rail guides 21 and 31 are coupled to each other, and the polymer slide fastening portion 40 slides the rail guides 21 and 31 of the light polymerization cup 20 or the heat polymerization cup 30. Inserted and the slide long hole 41 is formed a cross-sectional shape of the '' 'groove.

Therefore, while the upper portion of the light polymerization cup 20 or the heat polymerization cup 30 is supported by the polymerization slide fastening portion 40 of the slide long hole 41, the slide bonding is induced, the polymerization slide fastening portion 40 And each of the light polymerization cup 20 and the heat polymerization cup 30 will have a properly coupled state. Thus, the polymerization slide fastening portion 40, the light polymerization cup 20, and the heat polymerization cup 30, even by the expansion of the airtight tube 45 and the pressurization action by the air pressurizing portion 46, which will be proceeded later. Since the part is in a stable state, the pressurizing action and thus the light polymerization process and the light heat polymerization process are performed stably.

In addition, the LED lamp 42 is coupled to the upper side of the polymerization slide fastening portion 40 so that the LED light emitted from the LED lamp 42 is projected to the light-transmitting portion 43 in the center of the polymerization slide fastening portion 40. The light polymerization cup 20 or the heat polymerization cup 30 is provided so as to be reflected on the pore 11 located inside.

LED lamp 42 and the related members for this purpose, as shown in Figures 2, 5 to 7, etc., the LED lamp 42 and the LED operating portion 61 is provided in the rear, such as the LED cooling fan 421 3), as shown in Figure 3, the LED lamp 42, the LED operating unit 61, including the heat generated from the inside of the LED polymerization apparatus 10 upper side to be discharged to the rear to make a heat dissipation action will be.

When the control signal for the light polymerization process or the light heat polymerization process is transmitted from the polymerizer controller 60 to the member such as the LED lamp 42 by the start of the operation of the LED polymerization apparatus 10, the LED operation unit 61 ) Is activated so that the LED light is emitted from the LED lamp 42. When the LED lamp 42 and the LED temperature sensor (not shown) for the LED lamp 42 and the LED operating part 42 are determined to be high temperature by the sensed temperature detection signal during the light emitting process, the polymerization controller controller 60 uses the LED cooling fan. The 421 is operated to prevent the LED lamp 42 and the LED operating unit 61 from becoming high temperature.

As such, the LED ball emitted from the LED lamp 42 is dimmed in the pores 11 inside the light polymerization cup 20 or the heat polymerization cup 30. LED light is passed through the provided light-transmitting portion 43.

Therefore, unlike the embodiment of the accompanying drawings, the installation position of the LED lamp 42 may be installed so as to directly project the downward light emitting portion 43 from the upper portion of the light transmitting portion 43, and also by providing a reflecting mirror 431 For example, the LED light may be provided to reflect and shine at a right angle.

Accordingly, the light transmitting part 43 is to have an airtight state between the light transmitting part 43 and the polymerization slide fastening part 40 in order to allow the polymerization space 401 to have a pressurized state.

That is, as shown in FIG. 11, the light-transmitting unit 43 is installed in the upper light-transmitting space 432 of the polymerized slide fastening portion 40, and is provided with a transparent light-transmitting mirror 433 through which the LED light passes, and a light-transmitting mirror 433 is provided. The advertizing unit 434 to prevent the separation of the) is combined, and also between the floodlight 433 and the polymerization slide fastening portion 40 is provided with a light-transmitting packing 435 may be kept confidential.

Therefore, the LED light emitted by the upper LED lamp 42 and the reflecting mirror 431 is projected onto the pore 11 that is positioned in the polymerization space 401 below through the light transmitting mirror 433 of the light transmitting part 43. To lose.

And the air sealing tube 45 is provided around the light-transmitting portion 43 of the polymerization slide fastening portion 40, the expansion of the air sealing tube 45 of the light polymerization cup 20 or the heat polymerization cup 30 The upper portion and the lower portion of the polymerization slide fastening portion 40 are provided to be sealed.

The air sealing tube 45 is formed in a ring shape as shown in Figs. 9 and 10, the inlet 451 is provided upward, the ring-shaped air sealing tube 45 is a polymer slide fastening portion 40 It is inserted into the tube insertion hole 452 formed in the), the injection hole 451 is to penetrate and coupled with the upper outer side from the polymerization space 401 under the polymerization slide fastening portion 40. Therefore, when the air operating unit 63 is operated by the control of the polymerization reactor control unit 60, compressed air supplied from an external compressor (not shown) is injected into the inlet 451, and thus injected into the inlet 451. The air sealed tube 45 is expanded by the compressed air. As a result of the expansion of the air-sealing tube 45, the light polymerization cup 20 or the heat polymerization cup 30 is slide-bonded to the slide long hole 41 and positioned in the polymerization cup insertion hole 12 and the polymerization space 401. Between the upper surface and the polymerization slide fastening portion 40 is to maintain the airtight.

As such, when the air sealed tube 45 is expanded to become a sealed state between the polymerization slide fastening portion 40 and the light polymerization cup 20 or the heat polymerization cup 30, the air sealing tube 45 may be expanded by the expansion force by the air sealed tube 45. As a result, the light polymerization cup 20 and the heat polymerization cup 30 may be prevented from being separated from the polymerization slide fastening portion 40.

Due to the expansion operation of the air-sealing tube 45, first, the airtightness between the polymerization space 401 and the outside formed by the polymerization slide fastening portion 40 and the light polymerization cup 20 or the heat polymerization cup 30, etc. In the closed state, and second, the light polymerization cup 20 or the heat polymerization cup 30 is not easily separated during the polymerization process.

In this way, by allowing the polymerization space to be hermetically sealed to the outside, high pressure can be applied because the air injected during the subsequent pressurization action is not discharged to the outside, and thus high pressure is applied to the pore 11. In this case, bubbles of small pores inside the pore 11 can be easily released to the outside, and thus pores in a good state without bubbles are produced as shown in the cross-sectional example of FIG. 26.

In addition, since the light polymerization cup 20 or the heat polymerization cup 30 is not separated from the LED polymerization apparatus 10 during the polymerization process by the expansion force by the air sealing tube 45, the user can safely use the LED polymerization. The state of the apparatus 10 and the pore 11 can also be used favorably.

In particular, even if a slight external impact is applied during operation, since the polymerization space 401 can maintain a high pressure state, the formation of pores is also good and other members are not damaged.

In addition, the LED polymerization apparatus 10 according to the present invention is provided with an air pressurizing unit 46 for applying a high pressure air pressure into the light polymerization cup 20 or the heat polymerization cup 30, the air-sealing tube 45 After the airtight state by the air), the compressed air is injected into the polymerization space 401 by the air operating unit 63 and the air pressing unit 46 to be in a high pressure state.

In addition, in the LED polymerization apparatus 10 according to the present invention, the sample polymerization cups 22 and 32 of the light polymerization cup 20 or the heat polymerization cup 30 are made of tungsten, and the polymerization slide is further provided. It will be desirable to also provide the fastening portion 40 is made of tungsten. In addition, the polymerization slide fastening portion 40, the light polymerization cup 20 and the heat polymerization cup 30, etc., such as titanium, alloy, etc., are hard and wear well, and do not change even under high pressure and high temperature and do not change physical properties. If the material does not bring chemical and physical deformation to the contained pores inside may be selected in various ways.

In addition, the light polymerization cup 20 or the heat polymerization cup 30 positioned in the polymerization cup insertion hole 12 has a rail guide 21 and 31 protruded outwardly from the upper edge like a wing to form a polymerization slide fastening portion ( The slide is coupled along the slide hole 41 of the 40, whereby the polymerization space 401 is formed in the light polymerization cup 20 or the heat polymerization cup 30 below the polymerization slide fastening portion 40 will be.

In the polymerization space 401, the pore 11 to be subjected to polymerization is positioned. The pore 11 may be freely formed in a state, shape, or the like suitable for a dental treatment as an object of dental treatment. It is.

As such, the light polymerization cup 20 or the heat polymerization cup 30 which forms the polymerization space 401 together with the bottom of the polymerization slide fastening portion 40 includes a sample polymerization cup 22 in which the pores 11 are contained. It is to be provided with a polymerization case 24, 34 that surrounds the 32 and the handle 241, 341 is coupled to the front.

That is, the inside of the sample polymerization cups 22 and 32 of the light polymerization cup 20 or the heat polymerization cup 30, the pore 11, which is the object of polymerization, is positioned, and the polymerization slide fastening portion 40 As such, the sample polymerization cups 22 and 32 may also be made of a hard and non-deformable material such as tungsten.

In addition, each circuit may be configured inside the bottom of the polymerization cases 24 and 34, such as the light polymerization cup 20 or the heat polymerization cup 30, and a connector power source provided inside the polymerization cup insertion hole 12. Coupled with the terminal 13 to transmit and receive a signal related to the light polymerization cup 20 in the case of the light polymerization cup 20, or to transmit and receive a signal related to the heat polymerization cup 20 in the case of the heat polymerization cup 30 As a result, the polymerizer control unit 60 may determine the type of the polymerization cup by simply fastening the light polymerization cup 20 or the heat polymerization cup 30 before operation.

Of course, in addition to the connection signal connected to the connector power supply terminal 13, the polymerization controller control unit 60, even if the light polymerization cup 20 or the heat polymerization cup 30 does not transmit a separate response signal, It may be arranged to determine what the polymerization cup is. Thus, the polymerization controller control unit 60 may be provided to perform the polymerization process according to the program suitable for the polymerization cup, such as the combined light polymerization cup 20 or heat polymerization cup 30.

In particular, the bottom of the heat polymerization cup 30 is provided with a heater heating unit 342 that is heated by electricity is provided so that the heating action for the pore.

As described above, whether the heating operation is performed is different from that of the heat polymerization cup 30 and the light polymerization cup 20 for each signal plate by connection with the heater coil of the heater heating part 342 of the heat polymerization cup 30. It may be possible to determine that.

In other words, if a connection signal different from the heater coil is detected, the light polymerization cup may be determined. On the other hand, if the connection signal between the connection with the light polymerizer and the other heater coil is detected, the heater polymerization cup may be determined.

In addition, the pore 11 contained in the inside of the light polymerization cup 20 is contained, the light pore cup 25 to include a reflective bead 251 below the pore 11 may be provided will be. That is, when the LED light is shining from the top, as in the example of Figure 1, 5, 9, etc., the LED light may not be well reflected on the bottom of the pore. Therefore, when the pore 11 is positioned inside the light pore cup 25 in which the reflecting beads 251 are contained, the LED light reflected from the upper part is diffusely reflected to a large number of the reflecting beads 251, and such diffusely reflected LED light Is again reflected upwards, so that the bottom of the pore 11 can be evenly reflected evenly. Therefore, the LED light shines on the entire surface of the pores 11 by the reflective beads 251, so that the light polymerization process will proceed well.

In addition, the inner surface of the light pore cup 25 in which the reflecting beads 251 may also be provided as the LED light reflecting surface, the LED light is more evenly reflected by the LED light is evenly distributed throughout the pore 11 It can be arranged to be seen.

And the light pore cup 25 may be provided with a rim to prevent deformation.

In addition, the heat pore bond 35 in which the pores 11 contained in the heat polymerization cup 30 are contained is provided.

The heat polymerization cup 30 is that the pores 11 are contained in the heat pore bond 35, the heat polymerization cup 30 is a heater heating unit with a light polymerization process in which the LED light is illuminated under high pressure ( The light heat polymerization process in which the heat polymerization process by 342 is sequentially performed is performed, and may be made of a metal member so that the heat pore bond 35 is not damaged even during the heat polymerization process.

In the light heat polymerization process in which the heat polymerization cup 30 is combined, water is filled so that the pore 11 is contained therein, and the heat pore bond is removed so that the water is well removed when the pore is removed after the polymerization process is completed. 35 may be provided with a plurality of holes for drainage.

Therefore, while the light heat polymerization process is completed and taken out, the handle of the heat pore bond 35 in the heat polymerization cup 30 is pulled out and water is drained into the drain hole during this process, and water on the surface of the pore 11 is removed. This will be removed.

In addition, the polymerization cases 24 and 34 in the light polymerization cup 20 and the heat polymerization cup 30 support and move the sample polymerization cups 22 and 32 in which the pores 11 are contained. It is for convenience.

In addition, the circuits provided inside the bottoms of the sample polymerization cups 22 and 32 may be provided with members necessary for operation such as a sensor, and the members may be added and installed as necessary.

In the LED polymerization apparatus 10, the polymerization cup insertion hole 12 is connected to the light polymerization cup 20 or the connectors 23 and 33 of the heat polymerization cup 30. Or a connector power terminal 13 to transmit an electrical signal to the heat polymerization cup 30. Through the connector power supply terminal 13, a signal such as a light polymerization cup 20 or a heat polymerization cup 30 and a signal can be transmitted and received, and in particular, power is supplied to the heater heating unit 342 of the heat polymerization cup 30. Will be able to transmit.

Also, as shown in FIG. 8, a cup recognition switch 15 is provided next to the connector power supply terminal 13, and the light polymerization cup 20 or the heat polymerization cup 30 is cooled in the inner bottom of the polymerization cup insertion hole 12. Cooling fan 14 to be provided.

The cooling fan 14 is operated to cool when the LED polymerization apparatus 10 including the light polymerization cup 20 or the heat polymerization cup 30 becomes higher than necessary.

In addition, in the LED polymerization apparatus 10, the LED polymerization apparatus 10 is controlled to perform a polymerization process for the pores 11 contained in the light polymerization cup 20 or the heat polymerization cup 30, When the detection signal received from the temperature sensor 62 is determined to be overheated, the cooling fan 14 is controlled to operate, and the light polymerization cup 20 or the heat polymerization cup 30 is a polymerization cup insertion hole 12. The polymerizer control unit 60 to receive the signal coupled to the cup recognition switch 15 is provided.

Therefore, the LED polymerization apparatus 10 can be operated as a whole by the control of the polymerizer control unit 60. From the sensors at each position, it is determined whether or not the relevant members are located in the signal, temperature or humidity. It detects various signals such as signals, signals related to electric signals, and other pressure related signals, and transmits them to the polymerization controller 60. The polymerization controller 60 stores the signals in a memory and then detects them from the corresponding sensors. The value of the received signals is compared with the setting data for the corresponding position to determine whether or not abnormality.

After that, based on the determined data, continuous operation, such as cooling, heating, or pressurization or decompression will be performed.

In addition, the LED operation unit 61 is provided with the LED lamp 42 to emit light to the pore 11 by receiving the control signal of the polymerizer control unit 60 to emit light.

In addition, the air actuating unit 63 allows the air sealing tube 45 to expand and the compressed air is supplied into the light polymerization cup 20 or the heat polymerization cup 30 under the control of the polymerization reactor control unit 60. It is provided.

In addition, the pressurized air supplied to the air operating unit 63 is supplied from an external compressor (not shown), and the air hose connected to the compressor (not shown) is connected to the back of the LED polymerization apparatus 10 as shown in FIG. 3. It is connected to the air regulator 631 provided in the pressurized air is supplied to the air operating unit (63). In order to maintain a constant pressure by the air regulator 631, it will be preferable to maintain a pressure of approximately 85 psi ~ 100 psi.

When the compressed air at such a pressure acts on the pore 11 of the polymerization space 401, bubbles contained in the pore 11 may be smoothly removed.

And the back of the LED polymerization apparatus 10 is provided with an exhaust hose 632 connected to the air operating unit 63, the compressed air and the air sealed tube that was pressurized to the polymerization space 401 to the exhaust hose 632 ( The pressurized air supplied to 45 will be provided to be exhausted.

The heater heating unit 342 of the heat polymerization cup 30 is supplied to the LED polymerization apparatus 10 and receives the control signal of the polymerization controller control unit 60 through the connector power supply terminal 13 and the connector 33. ) Is provided with a power supply unit 64 to supply electricity to the heater heating unit 342 is heated.

Accordingly, as shown in FIG. 3, a power connector 641, a power switch 71, a fuse 643, and a circuit breaker 644 for preventing overload are provided on the rear surface of the LED polymerization apparatus 10. A relief switch 633 may also be provided to extract the compressed air from which the emergency was injected into the polymerization space 401.

In addition, the upper portion of the LED polymerization apparatus 10 is provided with a display panel 101 for monitoring the operating state of the LED polymerization apparatus 10, the display panel 101 is provided with a signal input portion and a display portion will be. The signal input by the signal input portion is transmitted to the polymerizer controller 60 of the LED polymerization apparatus 10 to process the corresponding input, and the notification display content transmitted from the polymerizer controller 60 is displayed on the display portion. The contents will be displayed.

In other words, a detailed embodiment of the display panel 101 includes a start button 102, a start button 103, a cancel button 103, a reset button 104, a reset button 104, a sleep button 105, and a sleep button 105. The operation display portion includes a 'RUN' display unit 106, a 'FINISH' display unit 107, a 'ERROR' display unit 108, and a status display window 109 in which a state appears.

Therefore, as will be described in more detail in the following embodiment of the operation, the user can input a desired command by the start button 102, the cancel button 103, the reset button 104, the sleep button 105, The 'RUN' display unit 106, the 'FINISH' display unit 107, the 'ERROR' display unit 108, and the status display window 109 are provided to display the operation state of the LED polymerization apparatus 10. will be.

Looking at the control method for controlling the LED polymerization apparatus 10 according to the present invention provided as described above, looking at each step of the polymerization process as follows.

First, the power supply 71 is supplied with power to the LED polymerization apparatus 10 by the operation of the polymerization operation preparation step (S01) to prepare the polymerization operation will be performed.

The polymerization operation preparation step (S01) may be prepared so that the operation preparation process including the buzzer sound generation process, the cooling fan check process, the display LED blink check process, the display window blink check process.

This polymerization operation preparation step (S01) is to perform a self-diagnosis to check the LED polymerization apparatus 10 in advance before performing the polymerization operation in the LED polymerization apparatus 10, an embodiment for the preparation step process in more detail Looking at, when the power line is plugged into the power connector 641 on the rear, the user turns on the LED polymerization apparatus 10 by switching the power switch 71 on (ON).

With this power supply, the polymerizer control unit 60 sequentially checks the pre-operational state of each device.

First, the status display window 109 of the display panel 101 is turned on to show that the program of the polymerizer controller 60 is started. And together with the buzzing sound. Accordingly, the status display window 109 is'

'It is made in the form of a, by the status display window 109'

Will be displayed to indicate the normal operation of the software.

Next, in the polymerization controller control unit 60, the cooling fan 14 (MAIN FAN) is temporarily operated to check whether the main cooling fan is operated, and the LED lamp 42 is turned off immediately after the LED cooling fan ( 421 will also be temporarily activated to check the operation of the LED lamp 42 and the LED cooling fan 421.

Thereafter, the operation state of these other members and the input values from the respective sensors are determined to determine whether they are in a normal state. After the self-diagnosis check is completed, the 'RUN' display unit 106 of the display panel 101 (DISPLAY PANEL) is checked. ) To operate in a blinking state.

As a result, the LED polymerization apparatus 10 will inform that the preparation state for performing the polymerization operation is completed.

Of course, in the case of performing the polymerization operation preparation step (S01) of the self-diagnosis, if an error occurs in the inspection of some members, the corresponding error message is notified to the display panel 101 or the alarm sound so that subsequent actions can be taken. Will be prepared.

In particular, in order to ensure that the cross-sectional state of the pores 11 produced by polymerization by checking the state of each operating member in detail, the pores 11 are contained or manufactured as in the conventional manner. If the condition is not solid and poor, it is because it is easily damaged during use in dental treatment. That is, even in the case of the small sized pores 11, in order to ensure that no voids or bubbles are generated, the state of the LED polymerization apparatus 10 is checked in detail through a polymerization operation preparation step (S01) through software of pre-diagnosis. The pore 11 is to be produced in a good state.

In the state in which the polymerization operation preparation step (S01) is performed and the preparation of the polymerization process is completed, the pore 11 before the polymerization to be manufactured by a generally known dental treatment method or a pore manufacturing method is prepared.

The pore 11 before polymerization is put in the light polymerization cup 20 or the heat polymerization cup 30, and the light polymerization cup 20 or the heat polymerization cup 30 is inserted into the polymerization cup insertion hole 12. The light polymerization process or the light hit polymerization process is performed.

Looking at the alternative process for the light polymerization process or the light heat polymerization process, the rail guide 21, 31 of the light polymerization cup 20 or the heat polymerization cup 30 is the slide hole of the polymerization slide fastening portion 40 A slide coupled along (41), the cup recognition switch 15 detects that the light polymerization cup 20 or the heat polymerization cup 30 containing the pores is located in the polymerization cup insertion hole 12, the polymerization controller control unit ( The polymerization cup position step S02 of transmitting the detection signal to 60 is performed.

1, 5, 6, and 8, the cup recognition switch 15 is provided inside the polymerization cup insertion hole 12 of the LED polymerization apparatus 10 together with the connector power supply terminal 13. When the light polymerization cup 20 or the heat polymerization cup 30 is put into the polymerization cup insertion hole 12 as shown in FIG. 7, the end of the light polymerization cup 20 or the heat polymerization cup 30 is combined. The cup recognition switch 15 is operated while pressing, and the activated signal is transmitted to the polymerization controller 60.

Therefore, the LED polymerization apparatus 10 determines that the light polymerization cup 20 or the heat polymerization cup 30 is inserted and coupled, and then checks whether the light polymerization cup 20 or the heat polymerization cup 30 is combined. Request signal is sent. The check request signal is transmitted to the light polymerization cup 20 or the heat polymerization cup 30 through the connector power supply terminal 13, and the light polymerization cup 20 or the heat polymerization cup 30 transmits a response signal. Will be sent.

Therefore, when the response signal transmitted from the light polymerization cup 20 or the heat polymerization cup 30 is determined by the polymerizer control unit 60, the status display window 109 of the display panel 101 becomes'

'Indicates that the light polymerization cup is coupled, and the light polymerization process will be performed by the user pressing the start button 102 of the display panel 101.

In addition, when it is determined that the heat polymerization cup 30, the status display window 109 of the display panel 101 '

'Indicates that the heat polymerization cup is coupled, and the light hit polymerization process will be performed by the user pressing the start button 102 of the display panel 101.

As described above, the polymerization process is performed after the polymerization cup position step S02 is performed, and the preliminary step of allowing the polymerization space to be in a state for polymerization before the polymerization process is performed in earnest will be performed.

First, after the polymerization cup positioning step (S02), the air operating unit 63 is operated by the control of the polymerization unit control unit 60 to expand the air sealing tube 45 under the polymerization slide fastening unit 40, and polymerization. The polymerization space sealing step S03 is performed to seal the polymerization space 401 formed into the slide fastening portion 40 and the light polymerization cup 20 or the heat polymerization cup 30.

As a result, the airtight tube 45 between the polymerization slide fastening portion 40 and the light polymerization cup 20 or the heat polymerization cup 30 is blocked from the inside of the polymerization space 401 and the outside to be in an airtight state.

Accordingly, the polymerization space 401 is sealed in a state where the polymerization slide fastening portion 40 and the polymerization space 401 inside the light polymerization cup 20 or the heat polymerization cup 30 are hermetically sealed by the polymerization space sealing step (S03). Compressed air is injected into the compressed air step (S04) to perform a pressurization process on the pores (11).

At this time, the pressure applied to the inside of the polymerization space 401 is about 60 to 100 psi, and compressed air is introduced for about 15 seconds. Since the light polymerization process is about 5 minutes, the light heat polymerization process is to maintain a high pressure for about 25 to 30 minutes.

As such, since the inside of the polymerization space 401 has a high pressure state, the pores 11 contained in the light polymerization cup 20 or the heat polymerization cup 30 are contracted by a high pressure in a state that is not yet hard. On the other hand, pores such as air contained in the pores 11 are to be released to the outside of the pores 11 by the pressure of the contraction.

Therefore, as shown in the tomography picture of FIG. 26, clean pores without bubbles are produced.

Thereafter, the LED lamp 42 is operated in the state in which the compressed air is injected into the polymerization space 401 by the compressed air pressure step S04 so that the LED light is reflected on the pores 11 in the polymerization space 401. By doing so, the light polymerization step (S05) is performed so that the photopolymerization process for the pores 11 is performed.

By the light polymerization step (S05), the pore 11 is a light (light) polymerization process, the shape of the pore 11 is formed by the light polymerization process. Of course, the light polymerization process can be performed several times, and during the light polymerization process many times, the shape of the pore 11 is modified or modified in a more elaborate shape. Therefore, the shape of the pore 11 is generally made by the light polymerization process through the lighting polymerization step (S05). It will be molded and manufactured firmly.

After the lighting polymerization step (S05) as described above, the light termination step (S06) to terminate the photopolymerization process by dimming the LED light for the pore.

When the light polymerization cup 20 is coupled to the light polymerization process as described above, a polymerization process such as a lighting polymerization step (S05) and a writing termination step (S06) will be performed, while the heat polymerization cup 30 is combined to write the light. In the case where the heat polymerization process is performed, a heating process is further added after the writing termination step S06 in addition to the writing polymerization step S05 to perform a polymerization process for the pores.

After the polymerization process is performed, the compressed air discharge step S08 may be performed so that the compressed air injected into the polymerization space 401 is discharged so that the pressurization process for the pore 11 is completed.

That is, the compressed air that has been pressurized in the polymerization space 401 by the operation of the air operating unit 63 by the control of the polymerizer control unit 60 will be exhausted to the outside through the exhaust hose 632.

The air sealing tube 45 is expanded between the polymerization slide fastening portion 40 and the light polymerization cup 20 or the heat polymerization cup 30 to maintain airtightness, such that the light polymerization cup 20 or the heat polymerization cup is contracted. A polymerization termination step S09 may be performed in which the 30 is capable of separation from the polymerization slide fastening portion 40 and the polymerization cup inserting hole 12 so that the polymerization process for the pores of the polymerization space 401 is terminated. will be.

In this way, if one polymerization process is performed by performing the polymerization termination step (S09), if necessary, the pores 11 in a more suitable state are manufactured by performing the polymerization process again.

The detailed process of the light polymerization process and the light hit polymerization process is as follows.

Referring to the light polymerization process, when the light polymerization cup 20 is positioned in the polymerization cup insertion space 12 in the polymerization cup position step (S02), the polymerization of the light polymerization cup 20 of the polymerization controller control unit 60 Determined by the combination, the polymerization space sealing step (S03), compressed air pressure step (S04), writing polymerization step (S05), writing end step (S06), compressed air discharge step (S08), polymerization end step (S09) The light polymerization process is performed sequentially.

That is, in the state of being ready for polymerization in the polymerization operation preparation step (S01), as shown in Figure 1, 5, 9, etc., such that the pore 11 is contained in the light polymerization cup 20, prior to the light pore cup (25) Fill the reflective beads 251 to an appropriate degree. In the state in which the pores 11 are placed on the reflective beads 251, the light pore cup 25 is contained in the sample polymerization cup 22 of the light polymerization cup 20.

Thereafter, the handle 241 of the polymerization case 24 on the front surface of the sample polymerization cup 22 is lifted and slowly inserted into the polymerization cup insertion hole 12 of the LED polymerization apparatus 10.

At this time, the rail guide 21 protruding like a wing around the upper edge of the light polymerization cup 20 gradually slides in accordance with the slide hole 41 of the polymerization slide fastening portion 40 installed on the polymerization cup insertion hole 12. Will be inserted.

In this way, the connector power supply terminal 13 inside the polymerization cup insertion hole 12 and the connector 23 of the light polymerization cup 20 are coupled to each other, and the end of the light polymerization cup 20 is the cup recognition switch 15. By pressing), the coupling of the light polymerization cup 20 is completed.

The signal from the cup recognition switch 15 is transmitted to the polymerization controller control unit 60 to determine that the polymerization cup is coupled to the polymerization cup insertion hole 12, and thereafter a response for diagnosing which polymerization cup is inserted. Request signal is sent. The response request signal is transmitted to the circuit of the bottom of the light polymerization cup 20 through the connector power supply terminal 13 and the connector 23, and the response signal of the light polymerization cup 20 in the circuit of the light polymerization cup 20. Will reply. Accordingly, the polymerizer control unit 60 determines the response signal to determine that the light polymerization cup 20 is coupled, thereby inserting the light polymerization cup 20 into the status display window 109 of the display panel 101. As "

'Will be displayed. In addition, the 'RUN' display unit 106 of the display panel 101 is turned on or flashes to indicate that the preparation of the light polymerization process is completed, so that the light polymerization cup 20 is coupled to the polymerization cup insertion hole 12. The polymerization cup positioning step (S02) is to be performed.

Accordingly, the user presses the start button 102 to proceed with the light polymerization process.

In the light polymerization process, the polymerization space sealing step (S03) is first performed, and the 'RUN' display unit 106 of the display panel 101 is turned on under the control of the polymerization controller control unit 60, and the air operation unit ( 63 is operated to expand the air sealing tube 45 under the polymerization slide fastening portion 40 so that the polymerization space 401 formed inside the polymerization slide fastening portion 40 and the light polymerization cup 20 is sealed. will be.

Thus, the interior of the polymerization space 401 and the outside is blocked by the air sealing tube 45 positioned between the polymerization slide fastening portion 40 and the upper portion of the light polymerization cup 20 to become an airtight state.

As such, the compressed air pressure step S04 is performed in a state where the polymerization space 401 in the state where the light polymerization cup 20 is positioned is blocked from the outside.

That is, in the state where the polymerization slide fastening part 40 and the polymerization space 401 inside the light polymerization cup 20 are hermetically sealed and sealed, the air operating part 63 is operated by the control of the polymerization controller 60 so that air is released. Compressed air is injected into the polymerization space 401 through the pressure portion 46. Thus, the pressing process for the pore 11 is made.

The pressure applied to the interior of the polymerization space 401 and the pores 11 is approximately 60 psi to 100 psi, and compressed air is introduced for about 15 seconds. After the light polymerization process, the high pressure is maintained for about 5 minutes, and the light irradiation is performed by the LED lamp while maintaining the high pressure.

As such, since the inside of the polymerization space 401 has a high pressure state, the pores 11 contained in the light polymerization cup 20 are hardened by high pressure in a state that is not yet hard, whereas the pores 11 Pore, such as air contained in the inside is to escape to the outside of the pore 11 by the pressure, the high-pressure pore 11 is manufactured in a clean state without bubbles.

The LED lamp 42 is operated in a state in which compressed air is injected into the polymerization space 401 by the compressed air pressure step S04 so that the LED light is reflected on the pores 11 in the polymerization space 401. The light polymerization step (S05) is performed so that the light photopolymerization process for the pores 11 is performed.

By the light polymerization step (S05), the pore 11 is a light (light) polymerization process, the shape of the pore 11 is gradually formed by the light polymerization process. Of course, the light polymerization process may be performed several times, and during the light polymerization process a plurality of times, the shape of the pores 11 may be obtained by modifying the shape or more precise shape. Therefore, the shape of the pore 11 is generally made by the light polymerization process through the lighting polymerization step S05. Thus, the light polymerization process is completed by allowing the pore 11 to have a certain shape by the light-healing process. Will be.

Therefore, the writing end step (S06) for terminating the light emission of the LED lamp 42 is performed.

After the light polymerization process is performed, the compressed air discharge step S08 may be performed so that the compressed air injected into the polymerization space 401 is discharged so that the pressurization process for the pore 11 is completed. That is, the compressed air that has been pressurized in the polymerization space 401 by the operation of the air operating unit 63 by the control of the polymerizer control unit 60 is exhausted to the outside through the exhaust hose 632.

In addition, the air-seal tube 45 which is maintained in airtightness by expansion between the polymerization slide fastening portion 40 and the light polymerization cup 20 is contracted so that the light polymerization cup 20 is polymerized slide fastening portion 40 and polymerization. The polymerization terminating step (S09) is performed to allow separation from the cup insertion hole 12 so that the light polymerization process for the pores of the polymerization space 401 is completed. Then, the polymerization terminating step (S09) causes the polymerization controller control unit 60 to turn off the 'RUN' display unit 106 of the display panel 101, while the 'FINISH' display unit 107 is turned on so that the light polymerization process is performed. It will be displayed so that the user knows that it has finished.

By such a light polymerization process, the pore 11 is not a very hard finished product, but will have a clean state without pores.

As such, the pores 11 that have undergone the light polymerization process are taken out of the light polymerization cup 20 and then the light heat polymerization process is performed.

That is, in the light heat polymerization process, the heat polymerization cup 30 is positioned in the polymerization cup insertion space 12 in the polymerization cup position step S02, and thus the coupling of the heat polymerization cup 30 in the polymerization controller control unit 60 is performed. Determined as, the polymerization space sealing step (S03), compressed air pressure step (S04), writing polymerization step (S05), writing end step (S06), compressed air discharge step (S08), the end of the polymerization step (S09) In addition to being performed sequentially, the heating polymerization step (S07) after the writing end step (S06) is to be further performed.

Looking at the light hit polymerization process in more detail as follows.

The pore 11 formed by the light polymerization process is removed from the light polymerization cup 20 and positioned in the sample polymerization cup 32 of the heat polymerization cup 30.

Prior to this, in the heat polymerization cup 30, the pore 11 is placed in the sample polymerization cup 32 of the heat polymerization cup 30 in the heat pore carrier 35 so that the pore 11 is positioned. In this heat-poring carrier 35, many holes are drilled, so that the moisture is well drained.

Then, the water is filled in the sample polymerization cup 32 of the heat polymerization cup 30 before the pore 11 is placed in the heat polymerization cup 30. And in order to prevent the action between the oxygen in the water and the pore 11 is administered an oxygen adsorbent (Oxygen Scavenger). This is to prevent the pore surface state from being changed by oxygen in the water during the light heat polymerization process for the pore.

In addition, the light heat polymerization process is performed in a state of containing water at a high temperature and high pressure, thereby forming a harder and better pore.

To this end, the heat pore tin 35 containing the pores 11 is placed in the water in which the coral adsorbent is administered to the sample polymerization cup 32 of the heat polymerization cup 30.

The heat polymerization cup 30 is slide-bonded to the polymerization cup insertion hole 12 of the LED polymerization apparatus 10 to perform the polymerization cup positioning step (S02).

In this way, the tip of the heat polymerization cup 30 presses the cup recognition switch 15 in the polymerization cup insertion hole 12 during the polymerization cup position step S02 with respect to the heat polymerization cup 30, and a signal for the polymerization reaction is generated. It is transmitted to the control unit 60. Of course, during the polymerization cup position step S02, the connector power supply terminal 13 and the connector 33 of the heat polymerization cup 30 are coupled, and the polymerization controller control unit 60 receives a response request signal for the combined polymerization cup. Will be sent.

The response request signal is transmitted to the circuit of the bottom of the heat polymerization cup 30 through the connector power supply terminal 13 and the connector 33, and the circuit of the bottom of the heat polymerization cup 30 is the heat polymerization cup 30. By transmitting the response signal, the polymerizer control unit 60 determines that the heat polymerization cup 30 is coupled to the polymerization cup insertion hole 12.

In this case, when it is determined that the heat polymerization cup 30 is inserted into the polymerization cup inserting hole 12 by the polymerization controller control unit 60, the status display window 109 of the display panel 101 is replaced with '

'To indicate that the heat polymerization cup is combined, and the' RUN 'display unit 106 of the display panel 101 is turned on or flashes to prepare for the light heat polymerization process.

Then, the user presses the start button 102 of the display panel 101 to perform the light hit polymerization process.

In the light heat polymerization process, the polymerization space sealing step S03 is performed as in the previous light polymerization process, and the 'RUN' display unit 106 of the display panel 101 is turned on under the control of the polymerizer control unit 60. The air actuating unit 63 is operated to expand the air sealing tube 45 under the polymerization slide fastening portion 40, and thus, the polymerization space 401 formed inside the polymerization slide fastening portion 40 and the heat polymerization cup 30. Is to be sealed.

As a result, the interior of the polymerization space 401 and the outside are blocked by the air-sealing tube 45 positioned between the polymerization slide fastening portion 40 and the heat polymerization cup 30.

As such, the compressed air pressure step S04 is performed in a state where the polymerization space 401 in the state where the heat polymerization cup 30 is positioned is blocked from the outside.

That is, in the state where the polymerization slide fastening portion 40 and the polymerization space 401 inside the heat polymerization cup 30 are hermetically sealed and sealed, the air operating portion 63 operates under the control of the polymerization controller control 60 so that air is released. Compressed air is injected into the polymerization space 401 through the pressure portion 46. Thus, the pressing process for the pore 11 is made.

The pressure applied to the interior of the polymerization space 401 and the pores 11 is approximately 60 psi to 100 psi, and compressed air is introduced for about 15 seconds. Since the high pressure state is maintained in the light heat polymerization process for about 25 to 30 minutes, while maintaining the high pressure light irradiation process by the LED lamp, and then the heating process is performed by the heater operation.

That is, since the interior of the polymerization space 401 has a high pressure state, the pores 11 contained in the heat polymerization cup 30 are densified and hardened by high pressure, and air contained in the pores 11 is also included. The pores of the back are released to the outside of the pore 11 by the pressure is produced in a clean state without bubbles.

The LED lamp 42 is operated in a state in which compressed air is injected into the polymerization space 401 by the compressed air pressure step S04, so that the LED light is reflected on the pores 11 in the polymerization space 401. The polymerization step (S05) is performed.

The light polymerization step (S05) is a pore (11) is a light (light) polymerization process, the shape of the pore 11 is formed to some extent by the light polymerization process.

Thereafter, the writing termination step S06 of terminating light emission of the LED lamp 42 is performed.

In the state in which the photopolymerization process by the LED lamp 42 is completed and the high pressure state is maintained, the light heat polymerization process in which the heating polymerization step further undergoes the heat polymerization process under the control of the polymerizer control unit 60 is performed. Proceed.

That is, the heating polymerization step (S07) is a heater heating unit 342 through the connector power terminal 13 and the connector 33 of the heat polymerization cup 30 in the power supply unit 64 in accordance with the control signal of the polymerization controller control unit 60. ) Is supplied with electricity, and heating is performed. Therefore, the heater heating part 342 of the bottom of the heat polymerization cup 30 is heated to heat the sample polymerization cup 32 of the heat polymerization cup 30 to perform the light heat polymerization process for the pores 11.

In the polymerization space 401 formed by the polymerization slide fastening portion 40 and the heat polymerization cup 30 by such a heating operation, the heating operation by the heater heating part 342 becomes a high temperature state, whereby the heat polymerization cup Water in the sample polymerization cup 32 of (30) is heated to become a high temperature state.

In particular, since the interior of the polymerization space 401 is a high pressure state, the water in the sample polymerization cup 32 is quickly heated to a high temperature, thereby having a high temperature state of about 80 degrees to 100 degrees.

Thus, since the water in the sample polymerization cup 32 has a high temperature and a high pressure state, the pores 11 contained therein are also surrounded by high temperature and high pressure water, thereby performing a heat polymerization process, thereby becoming a more solid state.

When it is determined that the heat polymerization cup 30, the heater heating unit 342, and the inside of the LED polymerization apparatus 10 are overheated to a high temperature during the heat polymerization process, the cooling fan is controlled by the polymerization controller control unit 60. (14) will be activated to allow the overheat to stabilize.

After maintaining the high temperature and high pressure of the heat polymerization process for about 15 minutes, the heat polymerization process is terminated.

That is, first, the heater is cut off from the supply of electricity supplied to the heating unit 342 and stops heating any more. And when the temperature is too high may be implemented to operate the cooling fan 14 to be a degree of harmless to the user.

In addition, the compressed air discharge step S08 is performed to discharge the compressed air that has been injected into the polymerization space 401 so that the pressurization process for the pore 11 is completed. That is, the compressed air that has been pressurized in the polymerization space 401 by the operation of the air operating unit 63 by the control of the polymerizer control unit 60 is exhausted to the outside through the exhaust hose 632.

In addition, the air-seal tube 45 that is maintained in airtightness by expansion between the polymerization slide fastening portion 40 and the light polymerization cup 20 is contracted so that the heat polymerization cup 30 is polymerized slide fastening portion 40 and polymerization. The polymerization terminating step (S09) is performed to allow separation from the cup insertion hole 12 so that the light heat polymerization process for the pores of the polymerization space 401 is completed. By the end of the polymerization step (S09), the polymerizer control unit 60 turns off the 'RUN' display unit 106 of the display panel 101, while the 'FINISH' display unit 107 is turned on so that the light hit polymerization is performed. This will indicate to the user that the process has ended.

By the light heat polymerization process, the pore 11 is manufactured in a very solid state.

The embodiments of the present invention have been described in detail above, but since the embodiments have been described so that those skilled in the art to which the present invention pertains can easily carry out the present invention, The technical spirit of the present invention should not be interpreted limitedly.

10: LED polymerization apparatus 11: pore
12: polymerization cup insertion hole 13: connector power supply terminal
14: cooling fan 15: cup recognition switch
20: light polymerization cup 21: rail guide
22: sample polymerization cup 23: connector
24: polymerization case 25: light pore cup
30: heat polymerization cup 31: rail guide
32: sample polymerization cup 33: connector
34: polymerization case 35: heat pore carrier
40: polymer slide fastening part 41: slide hole
42: LED lamp 43: floodlight
45: air sealing tube 46: air pressing unit
60: polymerizer control unit 61: LED operating unit
62: temperature sensor 63: air operation unit
64: power supply 71: power switch

Claims (6)

In the LED polymerization apparatus 10 is provided so that the polymerization of the light polymerization cup 20 or the heat polymerization cup 30 in which the pores 11 are contained, the polymerization action,
The LED polymerization apparatus 10 is formed with a polymerization cup insertion hole 12 into which the light polymerization cup 20 or the heat polymerization cup 30 is inserted,
The inner side of the polymerization cup insertion hole 12 is provided with a polymerization slide fastening portion 40 which is inserted into the light polymerization cup 20 or the heat polymerization cup 30 is inserted and coupled,
At the upper edge of the light polymerization cup 20 or the heat polymerization cup 30, rail guides 21 and 31 are formed to protrude in the shape of a wing and slide-couple with the polymerization slide fastening portion 40.
The slide guide 40 is inserted into the slide guides 40 and the rail guides 21 and 31 of the light polymerization cup 20 or the heat polymerization cup 30 to form a groove having a cross-sectional shape of a 'c' shape. An LED polymerization apparatus (41) is formed so that the upper portion of the light polymerization cup (20) or the heat polymerization cup (30) is supported by the polymerization slide fastening portion (40) of the slide long hole (41). .
The method of claim 1,
The LED lamp 42 is coupled to the upper side of the polymerization slide fastening portion 40 so that the LED light emitted from the LED lamp 42 is illuminated by the light-transmitting portion 43 in the center of the polymerization slide fastening portion 40. It is provided to be reflected on the pores 11 located inside the cup 20 or the heat polymerization cup 30,
The air sealing tube 45 is provided around the light-transmitting portion 43 of the polymerization slide fastening portion 40 and the upper portion of the light polymerization cup 20 or the heat polymerization cup 30 by the expansion of the air sealing tube 45. And the lower portion of the polymerization slide fastening portion 40 is provided to be sealed,
An air pressurizing unit 46 is provided to apply high-pressure air pressure into the light polymerization cup 20 or the heat polymerization cup 30.
The sample polymerization cups 22 and 32 of the light polymerization cup 20 or the heat polymerization cup 30 include tungsten,
LED polymerization device, characterized in that the polymerization slide fastening portion 40 is provided with tungsten.
The method of claim 1,
The signal is inserted into the polymerization cup inserting hole 12 and connected to the connectors 23 and 33 of the light polymerization cup 20 or the heat polymerization cup 30 to the light polymerization cup 20 or the heat polymerization cup 30. Is provided with a connector power terminal 13 to transmit the,
The light polymerization cup 20 or the heat polymerization cup 30 surrounds the sample polymerization cups 22 and 32 in which the pores 11 are contained, and the polymerization case 24 in which the handles 241 and 341 are coupled to the front. 34 is provided,
The bottom of the heat polymerization cup 30 is provided with a heater heating unit 342 that is heated by electricity is provided to perform a heating action for the pores,
A cooling fan 14 for cooling the light polymerization cup 20 or the heat polymerization cup 30 is provided at the inner bottom of the polymerization cup insertion hole 12.
A light pore cup 25 is provided so that the pore 11 contained in the light polymerization cup 20 is contained therein, and the reflective beads 251 are included under the pore 11.
LED polymerization apparatus, characterized in that the heat pore bond 35 that is contained in the pores (11) contained in the heat polymerization cup 30 is provided.
The method of claim 1,
The LED polymerization apparatus 10 is controlled to perform a polymerization process for the pores 11 contained in the light polymerization cup 20 or the heat polymerization cup 30, and a detection signal received from the temperature sensor 62. Is determined to overheat, the cooling fan 14 is controlled to operate, and the light polymerization cup 20 or the heat polymerization cup 30 is a signal coupled to the polymerization cup insertion hole 12, the cup recognition switch 15 Polymerizer control unit 60 to be transmitted from) is provided,
In response to the control signal of the polymerizer control unit 60, the LED lamp 42 is provided with an LED operation unit 61 for causing the LED light to shine on the pores 11,
The air operation unit 63 is provided to expand the air sealing tube 45 under the control of the polymerizer control unit 60 and to supply compressed air into the light polymerization cup 20 or the heat polymerization cup 30. Become,
Supplying electricity to the LED polymerization apparatus 10 and receiving the control signal from the polymerization controller control unit 60 to the heater heating unit 342 of the heat polymerization cup 30 through the connector power supply terminal 13 and the connector 33. LED polymerization device, characterized in that the power supply unit 64 is provided to supply electricity to heat the heater heating unit 342.
In the control method for controlling the LED polymerization apparatus of any one of claims 1 to 4,
A polymerization operation preparation step (S01) in which power is supplied to the LED polymerization apparatus 10 by the operation of the power switch 71 to prepare a polymerization reaction;
The rail guides 21 and 31 of the light polymerization cup 20 or the heat polymerization cup 30 are slide-bonded along the slide holes 41 of the polymerization slide fastening portion 40 to contain the light polymerization cups containing pores. 20) or a polymerization cup position step (S02) of detecting that the heat polymerization cup 30 is located in the polymerization cup insertion hole 12 and transmitting a detection signal to the polymerization controller control unit 60 by detecting it in the cup recognition switch 15;
After the polymerization cup positioning step (S02), the air sealing tube 45 under the polymerization slide fastening portion 40 is expanded by the control of the polymerization controller control part 60 to polymerize the fastening slide fastening portion 40 and the light polymerization cup 20. Or a polymerization space sealing step (S03) to seal the polymerization space 401 formed inside the heat polymerization cup 30;
By the polymerization space sealing step (S03), the polymerization slide fastening portion 40 and the polymerization space 401 inside the light polymerization cup 20 or the heat polymerization cup 30 is compressed into the polymerization space 401 in a sealed state. Compressed air pressure step (S04) so that the air is injected so that the pressing process for the pore 11 is made;
The LED lamp 42 is operated in the state in which the compressed air is injected into the polymerization space 401 by the compressed air pressure step S04 so that the LED light is reflected on the pores 11 in the polymerization space 401. Writing polymerization step (S05) to make the photopolymerization process for the pores (11);
A lighting termination step (S06) for terminating the photopolymerization process by dimming the LED light for the pores after the lighting polymerization step (S05);
Compressed air discharge step (S08) to discharge the compressed air that was injected into the polymerization space 401 to end the pressurization process for the pore (11);
The air sealing tube 45 is expanded between the polymerization slide fastening portion 40 and the light polymerization cup 20 or the heat polymerization cup 30 to maintain airtightness, such that the light polymerization cup 20 or the heat polymerization cup ( 30, the end of the polymerization (S09) to terminate the polymerization process for the pores of the polymerization space 401 to be separated from the polymerization slide fastening portion 40 and the polymerization cup insertion hole (12);
Control method of the LED polymerization apparatus characterized in that it is provided with.
6. The method of claim 5,
In the polymerization operation preparation step (S01), the operation preparation process including a buzzer sound generation process, a cooling fan check process, a display LED blink check process, and a display window blink check process are performed.
When the light polymerization cup 20 is positioned in the polymerization cup inserting space 12 in the polymerization cup positioning step S02, the polymerization control unit 60 determines that the light polymerization cup 20 is coupled, and thus the polymerization space. Light polymerization process in which the sealing step (S03), the compressed air pressure step (S04), the lighting polymerization step (S05), the writing end step (S06), the compressed air discharge step (S08), the polymerization end step (S09) are sequentially performed To make this happen,
When the heat polymerization cup 30 is positioned in the polymerization cup insertion space 12 in the polymerization cup positioning step (S02), it is determined as a combination of the heat polymerization cup 30 in the polymerization control unit 60, the polymerization space In addition to the sealing step (S03), the compressed air pressure step (S04), the lighting polymerization step (S05), the writing end step (S06), the compressed air discharge step (S08), the polymerization end step (S09) are sequentially performed, After the writing end step (S06) and the heat polymerization step (S07) is further performed to perform a light heat polymerization process,
The heating polymerization step (S07) is such that electricity is supplied from the power supply unit 64 through the connector power terminal 13 and the connector 33 of the heat polymerization cup 30 by the control signal of the polymerization controller 60. The heater heating part 342 of the bottom of the heat polymerization cup 30 is heated to operate the sample polymerization cup 32 of the heat polymerization cup 30 so that the light heat polymerization process for the pores 11 is performed. Control method of the LED polymerization apparatus, characterized in that.

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