GR1009677B - Dentistry multi-tools having their one operational end furnished with an oscillation mechanism - Google Patents

Abstract

The aim of the invention is the creation of a dentistry multi-tool allowing, via controlled oscillation of its one, at least, operational part, the easy and clean transfer, emplacement and treatment of small quantities of wax, ceramics and other biocompatible materials throughout the dental construction work by overcoming problems so-far caused by the absence of such a tool which is able to receive different operational oscillating parts such as a compact nozzle in different configurations and dimensions or a group of bristles; furthermore, said dentistry multi-tool is provided with operational surfaces enabling its additional utilization in various stages associated to the prosthetic construction work such as its controlled vibration for improving the cohesion of the material and/or the easy removal of the false abutments from the mould; the entire multi-stage prosthetic work is performed with the use of the invented dentistry multi-tool alone.

Description

DENTAL MULTITOOLS WITH OSCILLATION MECHANISM

A FUNCTIONAL EDGE

This invention refers to dental multitools that have an oscillation mechanism that allows the controlled oscillation of at least one of their functional parts located at their upper end. This oscillation allows the easy, effortless and clean deposition, transfer and processing of small amounts of wax and ceramic, resinous and other biocompatible materials during the process of manufacturing dental work by the dental technician. Such a tool in different versions has a functional oscillating part which is a solid nozzle in different formations and dimensions, or a group of bristles. In addition, the specific multi-tools have functional surfaces at their lower end that are used to perform additional applications in various related stages of the construction of the prosthetic work.

Nowadays, in the process of processing the prosthetic material in order to mix it, or form the desired shape in the prosthetic work, the dental technician uses tools that do not have an oscillation mechanism and make his work difficult and also limit the aesthetic performance of the prosthetic manufactured by him work. In addition, many of the dental tools require the repeated processing of their functional end by him throughout their use, where it is required on his part to repeatedly wipe the functional end with filter paper, or with the hand, or with the lips. Finally, in the various stages of the construction of the prosthetic work, the dental technician uses many different tools in order to implement the required procedures.

Today, dental technicians face a major problem with the limitations in design and operation of the available dental tools for mixing, transferring and shaping the prosthetic material in general that are available from the various companies.

The tools for transporting and shaping the prosthetic material available today on the market do not have a mechanism that allows the oscillation of their end. Thus, at various stages of the processing process, the shaping of the prosthetic material is carried out by the manual application of pressure by the dental technician, which cannot be identical throughout the process of manufacturing a prosthetic work that requires some hours, or even days to complete and which is affected by unpredictable factors such as fatigue, or the skill of the dental technician. In addition, especially in the cases of shaping ceramic material, the dental technician must periodically vibrate the ceramic prosthetic work holding tool in order to better compact the ceramic material. There are no tools available on the market that provide a safe way to methodically perform the above procedure, while there is an electric vibration device available today to perform the above procedure but the cost of which is very high.

The tools for mixing the prosthetic material available today on the market do not have a mechanism that allows the oscillation of their end, which makes it difficult and slows down the process of cleaning the functional end of the tool, since the dental technician is required to do this cleaning manually.

Commercially available dental tools whose working end has a group of bristles have a solid body which is the handle of the tool and a working end which is its head and which carries a solid group of independent bristles. The technique of using the specific tools in the process of manufacturing dental work from ceramic and resinous materials includes the following steps. First, the dental technician immerses the bristles of the tool in water in order to moisten them. He then rests the bristles of the tool on paper, or a sponge, or other absorbent medium to remove excess moisture from the bristles. He then places the bristles of the brush between his lips and by applying pressure and traction creates a solid shape with a pointed tip, which facilitates the detachment and transfer of small amounts of ceramic or resinous material. Then, he places the transferred material on the dental work and then repeats the aforementioned work steps in the same order until the dental work is completed. A first problem arising from the use of the above methodology is the increased working time resulting from the prerequisite steps of removing excess moisture from the bristles of the tool and the process of re-establishing the solid formation of the tip of the bristles after each transfer and placement step. of the ceramic, or resinous material. This process also often creates a second problem which is the alteration and destruction of the tip of the bristles of the tool from the repeated pressure exercises on them. Finally, the most important problem of all that arises from this process is the chronic contamination and burden on the dental technician's health from the chronic deposition of small amounts of ceramic and resinous materials in his body through his oral cavity.

In the process of checking the application of the prosthetic work on the mobile abutments of the working cast, the dental technician must remove and reposition the abutment on the cast by pushing the free end of its retaining pin, which is located at the base of the cast and within the mass of the latter. Accessing the pin to safely disengage the abutment requires the use of a tool with a special tip that is not commercially available.

Finally, the dental tools available on the market are designed to perform only one specific task, so the dental technician is required to have many different tools in order to implement the entire process of manufacturing a dental work, which significantly increases the cost of operation and maintenance of his laboratory.

Our invention is directed to dental tools, which have a spring or elastomeric cylinder oscillating mechanism in their upper end that allows the controlled oscillation of their upper functional end, while in addition they have a design that allows them to perform more than one function in the various stages construction of the dental work through the use of specially designed surfaces of their lower end.

This oscillating mechanism in a version of our invention that the operative end of the invented tool is a head with its free end in the shape of a knife, or spoon, or sphere, or triangle, or pyramid, or cube, or cylinder, or pole, or fork, allows the dental technician the easy and controlled formation of the shape of the wax in the wax phase of the framework of the work, but also of the prosthetic materials after their deposition on the metal framework, resulting from the casting of the wax, of the prosthetic work. This configuration is influenced by the vibration mechanism and is independent of the dental technician's fatigue. In addition, our invention has a handle with a special design, where in one part it has horizontal ridges that serve to vibrate a tool for holding prosthetic work made of ceramic material for better and controlled compaction of the ceramic material. Specifically, the dental technician brings the body of the forceps that holds the prosthetic work made of ceramic material into contact with the area of the handle that has ridges on its surface, having the two tools perpendicular to each other. It then moves the handpiece in a horizontal direction and in contact with the holding forceps allowing, through the grooves of the handpiece, the vibration of the body of the forceps and extension of the prosthetic work, which improves the process of densification of the ceramic material. He then continues the process of shaping the ceramic material with the functional upper end of the invented tool and repeats the whole process using the two functional parts of the tool, according to his needs, until the work is completed.

The oscillating mechanism of the invented tool in a version of our invention that the functional end of the invented tool is a head with its free end in the shape of a spatula allows the dental technician to quickly mix the components of the prosthetic materials of different composition and also to clean it easily with simply immersing the working end in a container of water and performing the oscillation. With this cleaning process, unwanted substances are prevented from being deposited on the surface by the hands of the dental technician, which can create a problem in the proper mixing and polymerization of the materials.

The oscillating mechanism of the invented tool in a version of our invention where the functional end of the invented tool is a head with bristles, allows the dental technician to safely, successfully and quickly remove excess moisture but at the same time restore the solid formation of the bristles brush on a generally pointed end. Thus the dental technician after immersing the bristles of the tool in water pulls the free end of the tool and then releases it allowing an oscillating process that directly makes the tool to hold and transfer ceramic and resin material in the prosthetic work. In this way, the tool of our invention does not require any processing of the bristles of its functional end by the dental technician, which reduces the working time and additionally protects the integrity of the free end of the bristles and, by extension, the lifetime of the tool. Even more important is that the mechanism of operation of the tool of our invention combined with the methodology of its use avoids the necessity of placing the bristles of the tool in the mouth of the dental technician, protecting his health from a chronic contamination of the deposition of prosthetic materials in his oral cavity.

Another advantage of the invented tool is that at the lower end of its handle it has a solid, sharp cone that serves to easily detach an abutment above the working mold. In particular, the dental technician with the tip of the cone pushes upwards the free end of the mobile abutment retaining pin located at the base of the working mold and releases the abutment from the latter. In this way, the dental technician does not need to use other tools that are not made for the function in question and protects them in this way from possible damage.

Finally, the design of the invented tool allows, through the use of differently designed functional ends, all of which are compatible with the rest of the tool, to quickly and easily modify and use the tool at different stages of the construction of the prosthetic work. This fact, combined with the design and function of the lower part of its handle, increases the range of applications of the tool and reduces the need to acquire and use many different tools by the dental technician, reducing operating costs and simplifying the latter's work.

It is understood that the above descriptions do not limit the shape and the range of applications of the functional ends of our invention which can be available in various versions following the methodology of controlled oscillation in order to facilitate the use and improve the performance of the latter through the oscillation mechanism that has.

The invention is described below by way of example and with reference to the attached drawings:

Figures 1, 6, 7, 8, 9 and 10 show a dental tool used for holding, transporting, depositing, mixing and processing ceramic, resinous and other biocompatible materials in the process of manufacturing a dental work. The invented tool (1.h) consists of a handle (1.a), an oscillation mechanism (1.b, 3.c, 3.d), a handle adapter (1.c), a head adapter (1. d), a head (1.e) and a functional end (1.0, 5.d, 5.e, 5.g, 5.h, 5.0)

Figure 2 describes the handpiece (2.d) of the dental tool (1.h) which is a cylinder of variable cross-section which is solid, or has through, or blind holes (2.a) in the side walls of a part thereof and has a surface smooth, or uneven with horizontal striations (2.e) in a part of it or in its entirety (figure 2). The handle has a blind hole (2.c) in the base located at its upper end (2.b) and a sharp conical end of smaller diameter at its lower end (2.g), while it is made of metal, or wood, or plastic, or ceramic material, and has a surface with a texture that is smooth, or rough while its diameter varies from three to fifty millimeters and its length varies from three to twenty centimeters.

Figure 3 describes the oscillation mechanism (3.c, 3.d) of the invented tool (1.h), which is a spring (3.c, 1.b), or an elastic cylinder (3.d). The spring (3.c) is made of metal, or elastic material and its diameter is smaller than the diameter of the blind hole of the upper end of the handle (2.c) while its length varies from five to twenty millimeters. The pitch of the spring (3.c), the diameter of its coils, the thickness of its wire and its hardness vary. The rubber cylinder (3.d) is solid, or transparent, and is made of elastomeric material with varying dimensions and hardness.

Figure 3 describes the handle adapter (3.e, 1.c), which is a solid cylinder of variable cross-section having a thread at its upper end (3.a) and a blind hole in the base located at its lower end (3 .b). The handle adapter (1.c, 3.e) is made of metal, or wood, or plastic, or ceramic, or elastomeric material. It has a surface that is smooth, or uneven and smooth, or rough and a diameter that is less than, equal to, or greater than the minimum diameter of the handle (1.a, 2.d) and a length less than that of the handle (1.a, 2.d). In another version of our invention, the handle adapter (3.g) does not have a thread at its upper end but has a magnetic mechanism (3.h).

Figure 4 depicts the head adapter (1.d, 4.g) which is a cylinder of variable cross-section descriptively divided into four sections (4.a, 4.c, 4.d, 4.e) as one piece (4 .g) and is made of metal, or wood, or plastic, or ceramic, or elastomeric material. The first part (4.a) is a cylinder of variable cross-section which at its base has a blind threaded hole (4.b, figure 4 section C - C) compatible with that of the thread of the handle adapter (3.a) . The first part (4.a) has a surface that is smooth, or uneven and smooth, or rough and a diameter that is less than, or equal to, or greater than the minimum diameter of the handle (1.a, 2.d) and a length less from that of the handle (1.a, 2.d). In another version of our invention, the head adapter does not have an internal thread in its blind hole but has a magnetic mechanism (figure 4 section C - C2, 4.h).

The second part (4.c) is a solid cylinder of variable cross-section and has a surface that is smooth, or uneven and smooth, or rough and a diameter smaller than the diameter of the first part (4.a) and a length equal to or less than the first part (4.a). The third part (4.d) is a solid cylinder with a diameter smaller than the diameter of the second part (4.c) and a length equal to or shorter than the first part (4.a) and a surface that is smooth, or rough, and smooth, or irregular. The fourth section (4.e) is a solid cylinder with a diameter larger than the third section (4.d) and at the same time equal to or smaller than the second section (4.c). The fourth part (4.e) has a surface that is smooth, or rough, and smooth, or uneven.

Figure 5 describes the head (5.a, 1.e) of the dental tool (1.h). The head (5.a) is a cylinder of variable cross section having a blind hole at the base of (5.c) and is made of metal, or wood, or plastic, or ceramic, or elastomeric material. The blind hole (5.c) has a diameter larger than that of the second part of the head adapter (4.c) and equal to or smaller than that of the first part of the latter (4.a). The head (5.a) has a surface that is smooth, or uneven and smooth, or rough and a diameter smaller than, or equal to, or larger than the minimum diameter of the handle (1.a, 2.d) while its length is less than that of the handle (I.a, 2.d).

Figure 5 further describes the working end of the dental tool (1.Θ, 5.d, 5.e, 5.g, 5.n, 5.Θ) which is a straight (5.e, 5.g, 5 .h), or curved (5.i) polymorphic muzzle of constant or variable cross-section and varying dimensions and shapes, or a group of independent hairs (5.d) that are natural, or synthetic. The functional end (1.θ, 5.d, 5.e, 5.g, 5.h, 5.θ) is connected to the upper end of the head (5.b).

Figure 6 describes a methodology for assembling the parts of the dental tool (1.h) of our invention in one piece and includes the following steps:

1. The oscillating mechanism (6.a, 3.c, 3.d) is placed inside the blind hole of the upper part of the handle (2.c) and is kept in this position by welding, or tight fitting of the lower part of ( 6.b).

2. The upper part of the swing mechanism (6.a, 3.c, 3.d) fits by tight fitting, or welding, in the blind hole of the handle adapter base (3.b) keeping the swing mechanism trapped and under pressure between of the handle and the handle adapter (6.c).

3. The head adapter (1.d, 4.g) is connected by screwing the internal thread (4.b) to the external thread of the handle adapter (3.a), or alternatively in another version of our invention (3 .g, 4.h) the two sections are connected to each other by magnetic attraction and mechanical assembly (6.d).

4. The functional end (5.d, 5.e, 5.g, 5.h, 5.th) is connected to the head (5.a) by welding, or tight fitting (6.e).

5. The second (4.c), third (4.d) and fourth (4.e) parts of the head adapter (4.g) are fitted with the blind hole of the head (5.c) by tight fitting, or welding (6-g).

For a better understanding of the above, we quote the following example:

In a first example (figures 7 and 8) we describe the methodology of using the dental tool of our invention (1.h) for the construction of a single crown made of ceramic or resinous material (8.b), where the functional end of the tool consists of from a group of hairs (5.d). Specifically, the dental technician, after manufacturing the working mold and the metal, or ceramic, or resin framework of the single crown, applies the framework to the working mold (figure 8) and begins the process of transferring and depositing the ceramic, or resin material onto the framework (8.a, figures 7 and 8). Specifically, the dental technician dips the bristles of the dental tool of our invention in water (7.a) and then with his finger pulls the upper part of the dental tool to one side (7.b) and then releases the head allowing the finally the realization of an oscillation (7.c). After the completion of the oscillation and the return of the head of the dental tool to its original fixed position (7.d), the removal of excess moisture from the hairs of the head (5.a) and the formation of the free end of the hairs in a generally point formation is achieved . Then, the dental technician captures, transfers and deposits a small amount of ceramic or resinous material on the framework of the prosthetic work (8.a). The dental technician repeats the aforementioned steps until the completion of the manufacturing process of the final work (8.b). Subsequently, the work undergoes the final stage of firing, or polymerization of the ceramic or resinous material, and in this way the manufacturing process of the prosthetic work is completed.

In a second example (Figures 9 and 10) we describe the methodology of using the dental tool of our invention for mixing the components of prosthetic materials, where the functional end of the tool is a spatula (9.b). Specifically, the dental technician transfers with the functional end of the tool (9.b) the desired amounts of the solid (9.c, 9.g) components of the prosthetic materials onto his work surface and then gradually impregnates the solids through the oscillating mechanism materials with the liquid component (9.e) and mixes them (9.d). After the end of mixing, he dips the working end (9.b) into a container of water (10.a) and oscillates the latter (10.b, 10.c) in order to safely clean its surface before its reuse (10.d).

Claims (11)

1. A dental tool (I.h) consisting of a handle (1.a) with functional surfaces (2.e, 2.g), an oscillation mechanism (1.b, 3.c, 3.d), a handle adapter (1.c, 3.e, 3.g), a head adapter (1.d, 4.g), a head (1.e, 5.a) and a working end (5.d, 5.e, 5.g, 5.h, 5.Θ) all connected as one piece (6.g, 1.h) and which tool improves through the oscillation of its head (7.c), the mixing processes , of collecting, transporting, depositing and shaping ceramic, or resinous, or acrylic, or other biocompatible material, or wax in the process of manufacturing dental prosthetic restorations (Figures 7, 8, 9, 10). 2. A dental tool (1.h) as claimed in claim 1, wherein the handle of the dental tool (1.a, 2.d) is a cylinder of variable cross-section which is solid, or has a through, or blind hole (2. a) on the side walls of a part of it and has a surface that is smooth, or uneven with horizontal ridges (2.e) on a part of it or all of it (figure 2). This cylinder has a blind hole (2.c) in the base located at its upper end (2.b, 1.g) and a sharp conical end at its lower end (2.g) and is made of metal, or wood, or plastic, or ceramic material and its surface texture is smooth or rough while its diameter varies from three to fifty millimeters and its length varies from three to twenty centimeters. 3. A dental tool (1.h) as claimed in claim 1, wherein the oscillating mechanism of the dental tool is a spring (3.c, 1.b). The spring (3.c) is made of metal, or plastic, or elastomeric material and its diameter is smaller than the diameter of the blind hole of the upper end of the handle (2.c) while its length varies from five to twenty millimeters . The pitch of the spring (3.c), the diameter of its coils, the thickness of its wire and its hardness vary. A dental tool (1.h) as claimed in claim 1, wherein the oscillating mechanism of the dental tool (3.d) is an elastic cylinder (3.d). The rubber cylinder (3.d) is solid, or transparent and is made of plastic, or elastomeric material with dimensions and hardness that vary and its diameter is smaller than the diameter of the blind hole of the upper end of the handle (2.c) while its length varies from five to twenty millimeters A dental tool (1.h) as claimed in claim 1, wherein the handpiece adapter of the dental tool (3.e, 1.c) is a solid cylinder of variable cross-section having a thread at its upper end (3.a) and a blind hole in the base located at its lower edge (3.b). The handle adapter (1.c, 3.e) is made of metal, or wood, or plastic, or ceramic, or elastomeric material. It has a surface that is smooth, or uneven and smooth, or rough and a diameter that is less than, equal to, or greater than the minimum diameter of the handle (1.a, 2.d) and a length less than that of the handle (1.a, 2.d). A dental tool (1.h) as claimed in claim 1, wherein the handle adapter of the dental tool (3.g) at its upper end has a magnetic mechanism (3.h). A dental tool (1.h) as claimed in claim 1, wherein the head adapter of the dental tool (1.d, 4.g) is a cylinder of variable cross-section which is descriptively divided into four sections (4.a, 4. c, 4.d, 4.e) as one piece (4.g) and is made of metal, or wood, or plastic, or ceramic, or elastomeric material. The first part (4.a) is a cylinder of variable cross-section which at its base has a blind threaded hole (4.b, figure 4 section C - C) compatible with that of the thread of the handle adapter (3.a) . The first part (4.a) has a surface that is smooth, or uneven and smooth, or rough and a diameter that is less than, or equal to, or greater than the minimum diameter of the handle (1.a, 2.d) and a length less from that of the handle (1.a, 2.d). The second part (4.c) is a solid cylinder of variable cross-section and has a surface that is smooth, or uneven and smooth, or rough and a diameter smaller than the diameter of the first part (4.a) and a length equal to or less than the first part (4.a). The third part (4.d) is a solid cylinder with a diameter smaller than the diameter of the second part (4.c) and a length equal to or shorter than the first part (4.a) and a surface that is smooth, or rough, and smooth, or irregular. The fourth section (4.e) is a solid cylinder with a diameter larger than the third section (4.d) and at the same time equal to or smaller than the second section (4.c). The fourth part (4.e) has a surface that is smooth, or rough, and smooth, or uneven. 8. A dental tool (I.n) as stated in claim 1, wherein the head adapter of the dental tool has a magnetic mechanism in its blind hole (figure 4 section C - C2, 4.n). 9. A dental tool (1.h) as claimed in claim 1, wherein the head of the dental tool (5.a) is descriptively a cylinder of variable cross-section having a blind hole at its base (5.c) and is made of metal, or wood, or plastic, or ceramic, or elastomeric material. The blind hole (5.c) has a diameter larger than that of the second part of the head adapter (4.c) and equal to or smaller than that of the first part of the latter (4.a). The head (5.a) has a surface that is smooth, or uneven and smooth, or rough and a diameter smaller than, or equal to, or larger than the minimum diameter of the handle (1.a, 2.d) while its length is less than that of the handle (I.a, 2.d). 10. A dental tool (1.h) as claimed in claim 1, the working end of which (1.0, 5.d, 5.e, 5.g, 5.h, 5.0) is a straight (5.e, 5.g, 5.h), or curved (5.0) polymorphic snout of fixed or variable cross-section and varying dimensions and shapes, or a group of independent bristles (5.d) that are natural, or synthetic. 11. A method of using the dental tool wherein the method includes: • The disposal and use of the dental tool (1.h) as mentioned in claim 1. • The method further comprises pulling and releasing the portion of the dental tool located beyond the oscillating mechanism towards the operative end thereof (7.b) • The free oscillation of the functional end of the tool (7.c) • The use or reuse of the tool after the completion of the oscillation (7.d, 8.a). • The use of the functional surfaces of the lower part of the handle with or without the oscillating process (2.e, 2.g).