DE4018107C1 - Electrically heated modelling appts. for dental wax - has heating element exhibiting large resistance jump upon reaching reference temp. - Google Patents

Abstract

The heating element (2) is made of ceramics material doped with barium carbonate or titanium oxide with a metallised coating at its edge zones. The heating element exhibits a rapid resistance increase at a defined temp. of between 150 and 180 deg. C. Pref. the heating element is located immediately adjacent the modelling tool (3) and has an associated brass sleeve (4), enclosed by a support insert (5) fitted to a plastics handle (7). ADVANTAGE - Prevents overheating of wax.

Description

The invention relates to an electrically heated modeling device with rapid heating phase according to the preamble of claim 1.

By modeling waxes in dental technology Shapes and models made. To do this, use of a heated wax instrument and applied specifically. There are two basic procedures and Devices known.

The first, most commonly used method is a hand instrument warmed over an open gas flame and used for wax modeling. The advantage of this Technology is that the user has the opportunity through the rapid heating and cooling of the instrument The degree of liquidity of the wax can be freely determined. Only through that Utilization of the gelation phase of the wax is a useful one Processing possible. The disadvantage is the use of a open flame, each only briefly to warm the Hand instrument is used, but always available must stand. Workplace stress from warming, bad air and an open flame hazard is given, with poor energy use and high Energy costs. Since there is no way that Processing temperature to a harmless to the waxes To limit value, overheats are common and pose due to uncontrollable shrinkage of the Wax models represent a reduction in quality. The correction of this Reductions represent a not inconsiderable amount of work The ergonomics are unfavorable because the instrument is always  which must be brought back into the flame for heating the concentration on what is common in dental technology Working area irritated.

The second method is based on the use of known ones electrically heated modeling equipment. Notes on known Devices are in DE 29 52 102 C2 and in DE 37 27 705 A1 Find. These devices use thermally slow for heating Cartridge heaters and allow a temperature setting that Initial temperature is constant. From US 43 01 357 a device known as a heat source in the flow direction operated semiconductor diode used, the thermal inertia comparable to a normal heating cartridge is. The heat sources are located on these devices completely or partially in the handles, what to their Warming, or unwieldy for thermal insulation reasons Dimensions leads, while increasing the thermal Inertia. A device is known that works at constant Flow temperature a user-controlled temperature increase allows. The heating up time for this temperature increase is too slow due to the radiator, also a following one Cooling phase back to the flow temperature.

These devices are used, in some cases in combination on the first procedure, but only from a limited one Part of users. The reason for the restricted Acceptance is the thermal inertia of the devices Modeling the wax using the softening and Complicate the gelling phase. Wax that is at a constant temperature is held, is difficult to apply to a working model build up.

A device is known in which a short-circuit heated tip used with short heating time becomes. The disadvantage is the very high peak temperature, that can lead to the annealing of the working tip and that Wax, even with intermittent operation of the control electronics, can overheat.

The invention has for its object a modeling device to create the disadvantages of the existing Techniques are eliminated, qualitatively and quantitatively  Get better results and manufacturing costs wax models as well as saving energy.

To achieve this object, the use of a radiator ( 2 ) leads to the characterizing part of claim 1.

The radiator ( 2 ) has a very high positive temperature coefficient and is a good electrical conductor when cold. After connecting to a circuit, the radiator heats up very quickly because a high current flows. When the reference temperature is reached, the volume resistance suddenly increases to a multiple of the cold resistance, the current flow drops sharply, the radiator temperature automatically settles to the reference temperature. It is possible to run the device with two different working tips ( 3 + 13 ) at the same time, which further increases the utility value and increases efficiency.

The advantages that can be achieved with the invention are that the user reaches the maximum working temperature at the working tip ( 3 ) by briefly defined closing of the circuit after a maximum of 4 seconds and this is not exceeded. Then a cooling phase begins again. In this mode, the predominant application - heating wax and applying it using the gelling phase - is simulated with an instrument heated in a flame without its disadvantages. For applications where a constant temperature below the reference temperature is required for special tasks, the voltage source is automatically switched periodically and with short pulses by the control unit in a further operating mode. By varying the ratio of pulse length to break length, any effective temperature below the reference temperature can be reached at the working tip ( 3 ). The thermal speed of the entire heating system makes it much easier to use in practice and improves acceptance of using an energy-saving, electrically heated device with all of its advantages.

The effort for power supply and control is low. The radiator is operated directly from a transformer with an alternating voltage of 24 volts and controlled by means of a switch or a foot switch or a touch sensor attached to the handle. For a possible constant temperature operation, a switchable free-running multivibration circuit with adjustable pulse and pause ratio has to be added. A simple fuse circuit prevents damage to the device if a short circuit between the support profile ( 1 ) and the support profile ( 4 ) should accidentally occur.

Any number of modeling devices with different working tips ( 3 ) can be operated on a control device with a switchover option. Due to the rapid heating up, there are no waiting times until operational readiness, the laborious changing of work approaches with the risk of burns is eliminated.

Further advantages, features and details of the invention result from the following description of an exemplary embodiment as well as from the drawing.

In Fig. 1 the sectional drawing of a device according to the invention is shown in an enlarged form. The original length is 13 cm from the tip ( 3 ) to the end of the handle ( 7 ).

Fig. 2 is an enlarged cross section through Fig. 1 along the line II-II.

Fig. 3 is a partial section from Fig. 1 with a second working tip ( 13 ).

The modeling device shown in Fig. 1 consists of a handle ( 7 ) made of plastic and an inserted insert ( 5 ) made of heat-resistant polyether ether ketone (PEEK). The insert socket ( 5 ) is the support for the entire heating system, makes it interchangeable and is locked in the handle with screw ( 6 ). The cable ( 8 ) connects the heating system to the circuit necessary for operation by means of screw ( 9 ).

The radiator ( 2 ) is soldered to the brass half-round support profiles ( 1 and 4 ) in the radiator area. In order to reduce the amount of material that can be heated and the associated storage capacity of heat, the cross-section of the support profiles ( 1 and 4 ) is reduced to a round profile right behind the radiator ( 2 ). The support profiles ( 1 and 4 ) are guided through two holes in the insert bushing ( 5 ) and cast in the cavity ( 10 ) with potting compound.

The layered structure of the heating system can be seen in FIG . The heating element ( 2 ) is provided with a solderable metallization on its edge zones ( 11 and 12 ). A solder paste is applied to these edge zones ( 11 and 12 ), radiators ( 2 ) are assembled with the support profiles ( 1 and 4 ) in the correct position, fixed and soldered in the furnace using the reflow method.

The shape of the working tip ( 3 ) shown in FIG. 1 represents a variant which is frequently used in the dental field. Such working tips can have probes, knives, spoons or custom shapes. The working tip ( 3 ) shown in Fig. 1 is made of the support profile ( 4 ) and made of the same material. This has the advantage of the most direct thermal coupling, but a separable design is also possible and within the meaning of claim 3.

Fig. 3, a partial section from Fig. 1 shows an embodiment variant according to claim 4 with two working approaches ( 3 and 13 ). In this case, the working tip ( 13 ) is made from the support profile ( 1 ), the working tip ( 3 ) from the support profile ( 4 ) and from the same base material. This arrangement is mainly suitable for applications with probe-shaped working tips. In these applications, coarse and fine application of wax requires probes with at least two different diameters. By simply turning the handle, you can work alternately with each probe without putting the device down or switching. A special feature is the use of the same radiator for two approaches.

The feature of a heating-up time of less than 4 seconds specified in claim 1 point d) is a maximum value. The exact value of the speed of heating depends on the size of the radiator ( 2 ), its reference temperature, the mass to be heated connected to the radiator and the level of the supply voltage. Depending on the size of the working tip, the values measured on the devices are 2.5 seconds on average. The maximum value of 4 seconds was safely undercut even with larger work approaches.

A calculation example shows the dynamic power consumption of the system. When cold, the nominal resistance is of the radiator 18 ohms, the supply voltage 24 volts, results in an inrush current of 1.3 amps and one Power consumption of 31.2 watts. When the reference temperature is reached, in the hot state, taking into account the continuous heat removal from the surrounding material and Medium, the resistance is 120 ohms. This results in with the same supply voltage, a current flow of 0.2 amperes and a power consumption of 4.8 watts.

Claims (4)

1. Electrically heated modeling device with rapid heating phase for processing dental waxes, characterized by the following features:

• a) the radiator ( 2 ) is made of a ceramic doped with barium carbonate and titanium oxide, which is provided at the boundary layer ( 11 ) and at the boundary layer ( 12 ) with a solderable metal contact and has an abrupt increase in resistance when the reference temperature is reached,
• b) the reference temperature of the radiator ( 2 ) is above 150 ° C and below 180 ° C.

2. Device according to claim 1, characterized by the following features:

• e) the heating element ( 2 ) is soldered to a first support profile ( 1 ) and a second support profile ( 4 ), outside an insert bushing ( 5 ) or a handle ( 7 ),
• f) the radiator ( 2 ) is in the immediate vicinity of a working part ( 3 ), at the ergonomically shortest possible distance.

3. Device according to claim 1 or claim 2, characterized by the following feature:

• g) the working part ( 3 ) is connected to the second support profile ( 4 ).

4. Apparatus according to claim 1 or claim 2, characterized by the following features:

• h) the working part ( 3 ) is connected to the second support profile ( 4 ) and made from the same piece,
• i) a further working part ( 13 ) is connected to the first support profile (1) and made from the same piece.