RU2624806C1 - Thermoelectric semiconductor device for thermoodontometry - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: thermoelectric semiconductor device for contrast thermoodontometry comprises an actuating tip, a thermoelectric system of exposure temperature change, a reference junction cooling system represented by a flow of a radiator, and a temperature control and regulation unit with a temperature sensor. The actuating tip is a gel material applicator with high thermal conductivity. The switching plates ends in the tip internal cavity protrude beyond the surface formed by the alternating p- and n-type branches on one side and represents the affecting junctions of the exposure temperature change system. The switching plates ends on the other side are in contact with the fluid circulating through the cooling system channel, and represents the reference junctions of the exposure temperature change system. The ends of the p- and n-type branches are coated with a layer of dielectric material with low thermal conductivity, and the projecting portions of switching plates - with a layer of dielectric material with high thermal conductivity. The exposure temperature control and regulation unit includes a power supply, a programmable controller, adigital display, an NC Portable key and a temperature sensor on the inner surface of the applicator. An electrically conductive expanding probe is located inside the dielectric insulating body with a possibiliti of lockeing in two positions.

EFFECT: increased accuracy of diagnosis, control and regulation of exposure temperature, improved device weight and size, improved quality of contact with the tooth surface, reduced process inertia under by changing temperature conditions, combination of heat and electrical exposure modes, increased speed of patient response accountig.

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Description

The invention relates to medical equipment and can be used in dentistry.

Determining the reaction of a tooth to temperature stimuli is one of the oldest physical research methods, widely used to determine the condition of the pulp.

Studying the reaction of pulp to irritants showed that a tooth with normal pulp reacts to significant temperature deviations. The indifferent zone (non-reaction zone) is 30 ° С (50-52 ° С - reaction to heat, 17-22 ° С - to cooling).

Teeth have both cold and thermal sensitivity. An adequate reaction (if heating and cooling cause a corresponding sensation) indicates the normal condition of the pulp. With inflammation of the pulp, a narrowing of the indifferent zone occurs and with slight deviations from body temperature (by 5-7 ° C), a response already arises in the form of prolonged intense or aching pain. In addition, with inflammation, an inadequate reaction is noted: pain arises from cold and warm. Teeth with necrotic pulp do not respond to temperature stimuli.

As an analogue, a thermoelectric device for temperature diagnostics and electroodontometry of the condition of the teeth [1] is considered, containing a copper probe placed in the housing, a thermoelectric battery in thermal contact with the copper probe and a flow radiator, a direct current source configured to set the exposure temperature, and temperature sensor located inside the housing.

The disadvantages of this device are its weight and size characteristics, the absence of an electric impact element in the device and the low accuracy of temperature diagnostics as a result of:

- small contact area and loose fit of the copper probe to the tooth surface;

- the inertia of the process due to the significant mass-dimensional indicator of the heat transferring part of the device, namely the probe and its base, in contact with the thermoelectric module;

- the remoteness of the temperature sensor from the acting part of the tip;

- lack of automatic change of temperature conditions;

- lack of feedback from the patient.

The aim of the invention is to increase the accuracy of diagnosis, control and adjustment of the temperature of the exposure, improve the overall dimensions of the device, improve the quality of contact with the tooth surface, reduce the inertia of the process when changing the temperature regimes, combine heat and electric effects, increase the speed of taking into account the patient’s feedback.

To address these shortcomings, a device is proposed comprising an applicator made of a gel material with high thermal conductivity, brought into contact with the surface of the tooth, the elasticity of which will ensure a tight fit of the applicator; a unit for monitoring and adjusting the temperature of exposure, including a power supply unit, a programmable control unit that allows you to set the pulse effect, a digital display, a portable disconnect key that provides a high speed of taking into account the patient’s feedback, and a temperature sensor located on the inner surface of the applicator to improve the accuracy of temperature determination exposure. The device also contains a thermoelectric system for changing the temperature of the impact, which consists of p- and n-type semiconductor branches alternating in a line connected by means of switching plates, the ends of the switching planes representing the acting junctions protrude beyond the surface formed by p- and n-type branches, on the one hand, and the ends of the connection plates representing the reference junctions, on the other hand. At the same time, the ends of the connecting plates representing the acting junctions enter the cavity of the applicator and come into contact with its highly heat-conducting gel material, which reduces the time it takes to reach the set temperature. The ends of the connecting plates representing the reference junctions are in contact with the fluid circulating through the channel of the cooling system. The ends of the p- and n-type branches are covered with a layer of material with low thermal conductivity, and the protruding parts of the patch plates are covered with a layer of dielectric material with high thermal conductivity. Using the pulse mode allows you to eliminate the inertia due to the small dimensions of the components of the thermoelectric system of temperature change, as well as create a time interval for recording the patient's response. To ensure electrical action, a conductive retractable probe with the possibility of fixation in two positions is placed inside the heat-insulating dielectric casing of the device.

The design of the proposed device is shown in FIG. one.

The device comprises an applicator 1 of a gel material with high thermal conductivity, which is in contact with a thermoelectric system for changing the temperature of the exposure. The thermoelectric system for changing the temperature of the action consists of p-4 and n-type semiconductors alternating in a line through the connecting plates 2 and 3. The ends of the switching platinum 2, representing the acting junctions, protrude beyond the surface formed by the p-4 and n- branches type 5, on the one hand, and the ends of the connecting plates 3, representing the reference junctions, protrude beyond the surface of the thermoelectric temperature change system on the other hand. In this case, the ends of the connecting plates 2, representing the acting junctions, enter the cavity of the applicator 1 and are in contact with its gel material, and the ends of the connecting plates 3, representing the supporting junctions, are in contact with the liquid circulating through the channel of the cooling system 6. System channel cooling 6 is a pipe of rectangular cross section, made of insulating dielectric material acting as a housing 7, one end of which is in contact with the ends of the switching plates 3, pr they are the supporting junctions of the thermoelectric system of temperature change, and the other end has two fittings 8 for connecting flexible tubes 9 and 10 with liquid circulating through them. Inside the pipe 7 of rectangular cross section parallel to the wide sides is a flat wall 11 made of heat-insulating material, dividing the cavity of the pipe into two parts. In one of the parts along the flexible tube 9, liquid is supplied that cools the ends of the connecting plates 3, which represent the reference junctions of the thermoelectric temperature change system. The ends of the branches p-4 and n-type 5 are covered with a layer of material with low thermal conductivity 12, and the protruding parts of the connection plates are covered with a layer of dielectric material with high thermal conductivity 13. The temperature control and adjustment unit 14 includes a power supply 15, a programmable control unit 16, a digital display 17. The temperature control and adjustment unit 14 is electrically connected to a thermoelectric temperature change system with an electrically conductive retractable probe 18 and a portable disconnect key 19. Programmable control unit 16, in turn, it is electrically connected to a temperature sensor 20 located on the inner surface of the applicator 1. An electrically conductive retractable probe 18 is located in the cavity of the insulating dielectric body 7 and is in contact with the dielectric springs 21 and the dielectric retainer 22 located in one of the fixing holes 23 or 24, respectively the position of the probe.

The principle of operation of the proposed device is as follows.

Before starting to use the device on the programmable control unit 16, the ascending or descending dynamics of the temperature effect is set, and the temperature corresponding to the given moment is displayed on the digital panel 17. The initial exposure temperature for any selected dynamics is set at 36 ° C. In accordance with the set temperature dynamics, the programmable control unit 16 delivers pulse signals to the power supply unit 15, setting the pulse value of the supply current supplied to the thermoelectric system of the temperature change of the exposure, which provides a pulse change in the temperature of the applicator. The temperature of the applicator 1 is controlled by a temperature sensor 20, the signals from which are fed to the programmable control unit 16. When passing through a pn-type semiconductor circuit, a constant electric current supplied from the power supply unit 15 between the connecting plates 2 and 3, which are the contacts of the p-4 and n-type 5 branches, a temperature difference occurs due to the release of Peltier heat at the other ends of the branches and the absorption at the other ends of the branches. When the direction of electric current flows from the n-type branches 5 to the p-type branches 4, the connection plates 3 are heated and the connection plates are cooled 2. In this case, due to the heat stabilization of the connection plates 3, carried out by means of a fluid circulating through the channel of the cooling system 6, the temperature patch plates 2 is maintained at a constant level during the current pulse. The exposure temperature of the applicator 1 is achieved due to the thermal contact of the connecting plates 2 with the gel highly thermally conductive material of the applicator 1. During the current pulse, the exposure temperature of the applicator 1 is set, which creates a time interval for recording the patient's response, which is fixed by pressing a button on the portable disconnect key 19 when the pain experienced by the patient. If this does not happen, the next current pulse is supplied, changing the temperature of the applicator by 1 ° C, in accordance with the upward or downward dynamics of the temperature change, while the magnitude of the exposure temperature is displayed on the digital display 17.

When using the function of exposure to electric current on the programmable control unit 16 sets the amount of electric current that is supplied to the electrically conductive retractable probe 18 from the power supply 15. When you click on the dielectric latch 22, located in the fixation hole 23 and fastened with an electrically conductive retractable probe 18, based on dielectric springs 21, it is possible to move the dielectric retainer 22 into the fixing hole 24, which allows you to extend the probe 18 from the heat insulating die electrical housing 7 and bring the probe 18 into contact with a biological object.

Literature

1. US patent No. 4350488 A, 09.21.1982. Dental pulp tester / Laurance B. Devis.

Claims (1)

A thermoelectric semiconductor device for thermoelectrodontometry, comprising an impact tip, a thermoelectric system for changing the impact temperature, a cooling system for support junctions in the form of a flow radiator, a control and adjustment unit for the impact temperature and a temperature sensor, characterized in that the impact tip is an applicator made of gel material with high thermal conductivity, in the inner cavity of which there are ends of patch plates protruding beyond a bridge formed by alternating p- and n-type branches, on the one hand, representing the acting junctions of the thermoelectric system, changes in the temperature of the action, and the ends of the connecting plates representing the supporting junctions, on the other hand, are in contact with the liquid circulating through the channel of the cooling system, the ends of the p- and n-type branches are covered with a layer of dielectric material with low thermal conductivity, and the protruding parts of the connection plates are covered with a layer of dielectric material with high thermal conductivity, p At the same time, the exposure temperature control and adjustment unit includes a power supply unit, a programmable control unit, a digital display, a portable disconnect key and a temperature sensor located on the inner surface of the applicator, and an electrically conductive retractable probe with the possibility of fixation in two positions is placed inside the dielectric heat-insulating case of the device.

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