RU2479249C2 - Patient skin cold and warm receptor density sensor - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention refers to medical equipment, more specifically to diagnostic systems based on temperature skin sensitivity detection. A patient skin cold and warm receptor sensor comprises a thermode (3), a thermode temperature sensor and metre (7), a heat module (1), which implements the Peltier effect and containing heat exposure (2) and heat exchanger (4) surfaces, radiator system (5), a direct current source (10), a first switch (11), a second switch (13), a control signal generator (14), a dual-channel temperature metre controller (12), a pulse counter (16), a patient-controlled pulse generator (15). The thermode (3) is equipped on the heat exposure surface (2) of the heat module (1); the radiator system (5) is placed on the heat exchange surface (4) of the heat module (1); a temperature sensor (7) is positioned in the thermode channel (3). Outputs of the direct current source (10) are connected to inputs of the first switch (11); outputs of the first switch (11) are connected to poles of the heat module (1); outputs of the temperature sensor (7) are connected to inputs of the dual-channel temperature metre controller (12). Each switching output of the dual-channel temperature metre controller (12) is connected to one of the two inputs of the second switch (13); output contacts of the second switch (13) are in a circuit of the power supply of the heat module (1). An output of the control signal generator (14) is connected in parallel to control inputs of the first and second switches (11, 13), and an output of the pulse generator (15) is connected to an input of the pulse counter (16).EFFECT: invention shall simplify the heat circuit of temperature skin sensitivity detectors.4 cl, 3 dwg

Description

The invention relates to the field of medical equipment, and specifically to diagnostic devices based on determining the temperature sensitivity of human skin.

The closest in technical essence and the achieved result to the proposed device includes a Belikova Z.P. thermoesthesiometer containing cooling and heating units made in the form of conical glass vessels filled either with hot water or with finely ground ice, a needle-shaped thermode installed at the tip of the vessel, a sensor and a temperature indicator in the form of a mercury or alcohol thermometer (see RF Patent 2392844).

A disadvantage of the known device adopted as a prototype is the complexity and cumbersomeness of the thermal circuitry used to determine the temperature sensitivity of the skin areas, which involves the use of cooling and heating units, which are not directly included in the device, of the water poured into the vessels to temperatures t _stmax and t _stmin , the complexity of changing the amplitude temperature of the thermode stating in accordance with the subjective characteristics of the patient.

The objective of the invention is to simplify the thermal circuit of the device for determining the temperature sensitivity of human skin.

The specified technical result is achieved by the fact that the device for determining the number of cold and thermal receptors on the patient’s skin area contains a thermode, a sensor and a thermometer for measuring the temperature of the device, and a thermal module that implements the Peltier effect and contains heat-acting and heat-exchange surfaces, a radiator system, a source is included in the device direct current, first switch, second switch, control signal generator, two-channel temperature controller, pulse counter, controllable The patient generates a pulse generating unit, the thermode is installed on the heat-acting surface of the thermal module, the radiator system is located on the heat-exchange surface of the thermal module, the temperature sensor is placed in the channel of the thermal module, the outputs of the DC source are connected to the inputs of the first switch, the outputs of the first switch are connected to the poles of the thermal module, the outputs of the temperature sensor are connected to inputs of a two-channel controller-temperature meter, each switching output of a two-channel controller-temperature meter It is connected to one of the two inputs of the second switch, the output contacts of the second switch are inserted into the power supply circuit of the thermal module, the output of the control signal generator is connected in parallel with the control inputs of the first and second switches, and the output of the pulse generating unit is connected to the input of the pulse counter. The pulse generating unit is made in the form of a button closure or in the form of a microphone.

The first channel of the temperature controller-meter is made with the possibility of stabilizing the temperature of the thermostat at the lower level in the range from minus 15 ° С to 20 ° С, and the second channel of the controller-temperature meter is made with the possibility of stabilizing the temperature of the thermostat at the lower level in the range from 35 ° С 60 ° C.

The invention is illustrated graphic materials.

Figure 1 schematically shows the design of the actuating element of the thermoesthesiometer, figure 2 shows the electrical circuit of the proposed device, figure 3 - dashboard of the power supply and control.

Structurally, the proposed device consists of three units: a power and control unit, an actuator, a patient-controlled pulse-generating unit.

The composition of the actuator includes (Fig. 1) a semiconductor thermal module 1 that implements the Peltier effect, containing a heat-acting surface 2 on which the thermode 3 is mounted, a heat-exchange surface 4, on which the radiator system 5 is installed, blown by fan 6.

Structurally, the thermode 3 is made in the form of a pointed body with a heat-contact plane, a channel is made inside the body for placement to ensure good thermal contact, a miniature temperature sensor 7.

According to the heat-contact surface, the thermode 3 is installed on the heat-acting surface 2 of the thermal module 3. Since the thermal receptors lie in the thickness of the skin, forming a mosaic of thermal spots, each with a diameter of about 1 mm, the value of the area of the pointed end of the thermode is in the range of 0.8-1.5 mm ² .

The actuating element of the thermoesthesiometer is equipped with a handle 8 in which a channel is made for accommodating a portion of the cable 9 connecting the actuating element with the power and control unit.

The electric circuit of the proposed thermoesthesiometer includes (Fig. 2) a direct current source 10, outputs connected to the inputs of the first switch 11, the outputs of which, in turn, are connected to the poles of thermal module 1, a two-channel temperature controller-meter 12, with inputs connected to the outputs a temperature sensor 7 located in the channel of the thermode 3, and each switching output is connected to one of the two inputs of the second switch 13, the output contacts of which are inserted into the power supply circuit of the thermal module 1.

The control unit also includes a control signal generator 14, the outputs of which are connected in parallel with the control inputs of the first switch 11 and the second switch 13, a patient-controlled pulse generating unit 15, connected to the input of the pulse counter 16 via an output cable 17.

As an example of a specific embodiment, the pulse generating unit 15 can be made in the form of a button closure placed in the patient’s hand, or a microphone placed in the patient’s mouth, etc.

The first switch is designed to reverse the polarity of the voltage supplied to the poles of the thermal module 1 from the DC source 10.

On the dashboard (Fig. 3) of the control unit there is a toggle switch 18 for connecting the device to the power supply, a toggle switch 19 for turning on the DC source 10 and supplying voltage to the thermal module 1 and fan 6, the switch 20 for controlling the generator 14, the blue LED 21, signaling that thermal module 1 is operating in cooling mode of thermode 3, LED 22 is red, signaling that thermal module 1 is operating in heating mode of thermode 3, panel 23 digital counter 16 pulses, panel 24 dual-channel controller -izmeritelya temperature 12, outlet 25, plug connectors for cable actuator 9, socket 26 for connecting cable plugs 17 block 15 generates pulses.

The proposed device operates as follows.

Connect the power and control unit to the power supply via a network cable with a plug (not shown).

Insert the plug of the cable 9 into the socket 25 on the dashboard to connect the actuator.

Insert the plug of the cable 17 into the socket 26 to connect the pulse generating unit 15.

Toggle switch 18 to the "On" position. In this case, the number “0” lights up on the display 23 of the digital pulse counter 16, and on the display 24 of the temperature controller-meter 12, the numbers carrying information about the temperature of the thermostat 3 light up in accordance with the signals received from the temperature sensor 7 installed inside it.

Switch 20 is moved to one of the positions determining the operation of thermal module 1 either in cooling mode or in heating mode. In this case, either blue 21 or red 22 LEDs light up.

Using the ↑, ↓, PROG buttons (not shown) set on the scoreboard 23, in accordance with medical requirements, the values of the upper t _stmax and lower t _stmin thermostat modes of thermostat 3 during the procedure for measuring the number of thermal and cold thermoreceptors in the area of human skin.

The patient is provided with a pulse generating unit 15. As an example of a specific embodiment, a button closure is placed in the patient’s palm or a microphone is placed in the mouth.

The subject is explained in advance to the essence of the method, which consists in the fact that after the occurrence of a single point sensation of cold or heat, the patient must send an impulse to the input of the counter 16 through block 15.

Toggle switch 19 is in the "On" position. In this case, the thermal module 1 begins to work in a previously set heat exposure mode, for example, in cooling mode.

After 10-15 minutes of adaptation, the patient begins to apply the chilled end of the thermode to various points of the skin site at room temperature, revealing the number of functioning cold receptors by the patient’s response. Dividing the detected number Nx of cold receptors by the area of the skin site on which the studies were performed, determine the value of the number n _{x of} cold receptors per unit area of skin:

Switch 20 is moved to a different position. In this case, the first switch 11 changes the polarity of the voltage supplied to the thermal module 1 from the direct current source 10, as a result of which the heating mode begins to be implemented on the heat-acting surface 2 of the thermal module.

Moreover, from the generator 14 to the control inputs of the first switch 11 and the second switch 13 receives a control signal of a different magnitude. The switch 13 connects to the power supply network of the thermal module 1 the second switching output of the two-channel controller-temperature meter, ensuring that the temperature of the thermode is maintained at the level of t _stmax . The identification of the number of functioning thermal receptors is carried out according to a method similar to that described above for cold receptors.

The proposed design provides a simplification of the thermal circuit and the overall configuration of the device designed to implement the process of determining the temperature sensitivity of the skin area of a person, in particular, provides the ability to precision thermostat thermostat both during cooling and when heating directly with the units included in its composition without the use of additional external devices , the ability to accurately correct the upper and lower stating temperatures, meets modern requirements, pre declared to medical equipment products.

Claims (4)

1. A device for determining the number of cold and thermal receptors on a patient’s skin area, containing a thermode, a sensor and a thermometer for measuring the temperature of a thermode, the device incorporating a thermal module that implements the Peltier effect and containing heat-acting and heat-exchanging surfaces, a radiator system, a direct current source, the first switch, second switch, control signal generator, two-channel controller-temperature meter, pulse counter, patient-controlled pulse-generating unit, thermode installed on the thermally acting surface of the thermomodule, the radiator system is placed on the heat-exchanging surface of the thermomodule, the temperature sensor is placed in the thermod channel, the outputs of the DC source are connected to the inputs of the first switch, the outputs of the first switch are connected to the poles of the thermomodule, the outputs of the temperature sensor are connected to the inputs of the two-channel temperature controller , each switching output of a two-channel controller-temperature meter is connected to one of two inputs of the second commutator torus, the output contacts of the second switch circuit incorporated in a thermo electrical generator control signals output in parallel is connected to the control inputs of the first and second switches, and a pulse generating unit output is connected to the input of the pulse counter. 2. The device according to claim 1, characterized in that the pulse generating unit is made in the form of a button closure. 3. The device according to claim 1, characterized in that the pulse generating unit is made in the form of a microphone. 4. The device according to claim 1, characterized in that the first channel of the temperature controller-meter is capable of stabilizing the temperature of the thermode at a lower level in the range from minus 15 ° C to 20 ° C, and the second channel of the temperature controller-meter is made with the possibility of stabilization temperature of the thermode at the upper level in the range from 35 ° С to 60 ° С.