RU2700591C1 - Thermometer with thermal insulation for bottle - Google Patents

Abstract

FIELD: home appliances.

SUBSTANCE: invention relates primarily to household appliances. Temperature measuring device is located on bottle neck, and neck itself and temperature sensor are covered with heat insulator.

EFFECT: use of the invention allows more accurate measurement of temperature of liquid in bottle during cooling / heating of bottle.

7 cl, 2 dwg

Description

FIELD OF THE INVENTION

The present invention relates mainly to household appliances and can be used to measure the temperature of a liquid (wine, water, etc.) in a bottle.

State of the art

There are various thermometers for liquid bottles in the world. In the application US 2006/0026971 A1 describes a thermometer with a display, which is placed on the neck of the bottle. GB 2516006 describes a thermometer with a radio interface that is located on the surface of a bottle and transfers the temperature of the liquid in the bottle to a smartphone. The closest analogue is US 9511910 B2. In all of the above options, thermometers accurately show the temperature of the liquid in the bottle if the atmosphere-bottle system is in relative thermodynamic equilibrium. But with quick cooling of the bottle (and liquid), for example, in the freezer, the readings of the thermometers will be very different from the temperature of the liquid in the bottle, because they will measure the air temperature in the freezer more because of the relatively low thermal conductivity of the glass.

SUMMARY OF THE INVENTION

Thus, it is an object of the present invention to provide a bottle thermometer that can more accurately measure the average temperature of a liquid in a clogged bottle in case of accelerated heating or cooling of the bottle.

To achieve the specified technical result, a thermometer for a bottle containing a temperature sensor is proposed; a microprocessor device that receives data from a temperature sensor; a holder securing said sensor above or on the neck of the bottle and providing such a placement of said sensor that the sensor is capable of sensing temperature values from a portion of the surface of the neck of said bottle; characterized in that the sensor senses thermal energy, most of which comes from the portion of the neck of the bottle, which does not come into contact with the cork plugging the bottle from the inside of the bottle; contains a heat-insulating device that prevents heat transfer from / to at least most of the outer surface of the neck of the bottle and said sensor / sensor, but does not prevent heat transfer from / to most of the outer surface of the bottle as a whole. In this case, the holder is not necessarily directly attached to the sensor, and, for example, the holder is screwed to a thermally insulating device, and the sensor is glued to a thermally insulating device.

The bottle thermometer of the present invention may include a device that prevents the movement of air from or into the insulating device.

The bottle thermometer may contain a pile serving as a heat insulator and / or holder. In another case, the pile may be present in the device, preventing the movement of air.

For faster installation of the thermometer on the bottle, the components of the said thermometer can have mechanical connections between themselves.

For more accurate measurements, as well as in the case of a display, the microprocessor device can be located outside the thermally insulating device.

Finally, the thermally insulating device may comprise foamed plastic.

Brief Description of the Drawings

In FIG. 1 shows an embodiment of a thermometer with thermal insulation for a bottle.

In FIG. 2 shows an option for mounting a thermometer on a bottle.

DETAILED DESCRIPTION OF THE INVENTION

The thermally insulated bottle thermometer of the present invention can be implemented in several versions, which, however, are implemented in a similar manner. It is clear that the larger the surface area of the bottle in contact with the cooler or heater, the faster the temperature of the liquid in the bottle changes. Therefore, most of the surface of the bottle should not be covered with thermal insulation, only the neck is optimally insulated. And also because of the poor thermal conductivity of the air, the fastest way to cool / heat is to place a temperature on the surface of the bottle of the battery, for example, Ezetil SOFT ICE FLEXIBLE.

In FIG. 1 presents another possible application of the invention, providing the desired technical result. The bottle of liquid 1 is located in a position close to horizontal or horizontal. Microprocessor unit 2 with a sensor 3 measures the temperature of the surface area of the neck of the bottle. It is important that immediately below the sensor 3 in FIG. 1 was a liquid, not a plug, so that the temperature of the outer surface of the neck was closer to the temperature of the liquid. The neck of the bottle is surrounded by a thermal insulator 4 (thermal insulating device), shown in section. It can be a hollow cylinder with one bottom made of foam plastic (polyethylene foam, polystyrene foam) or a “glass” made of hard plastic, inside of which fur (artificial or natural) with a long hard pile is glued on the walls. In a variant with fur, the thermal insulator 4 will be held on the neck with a pile. At the same time, the pile will also prevent air convection inside the thermal insulator 4. If the thermal insulator 4 does not have a fur inside, then it can be held on the neck using brass spring strips 5 bent in the form of a half ring, as shown in FIG. 2. (two strips of four are shown). The strips 5 are attached to the heat insulator 4 using self-tapping screws 6. To prevent air convection, the right side of the heat insulator 4 in FIG. 1 can be equipped with a fabric barrier attached to the heat insulator 4, which is tightened around the neck with a cord / elastic band, or a ring of pile. In another embodiment, it may be a rubber ring fixed to the body of the insulator 4 and in contact at the expansion point of the neck of the bottle 1 in FIG. 2.

The thermometer may have an electronic temperature sensor, for example, an analog LM35 or digital LMT01. A microprocessor device, for example, can be a STM32 microprocessor powered by batteries or a battery with a “strapping” on a printed circuit board, which receives data from a temperature sensor via electrical conductors (circuit jitter, wires) and transmits them via electrical conductors to a wireless Bluetooth or WiFi module (transceiver) or LCD. The sensor, microprocessor with strapping and Bluetooth module can be soldered to a printed circuit board, which is located in a plastic case or the case can serve as a thermal insulator. At the same time, part of the sensor surface (and maybe the entire sensor) must be placed outside the microprocessor unit housing so that this sensor surface is in contact with the surface of the bottle. In another embodiment, the sensor may be in contact with a copper plate curved along the radius of the neck, which serves as a heat conductor, and already the copper plate is in contact with the surface of the bottle. In another embodiment, the sensor may be a non-contact pyrometer. Moreover, in the case of using fur, the fur near the pyrometer will have to be removed. In the case of contact sensors, they (or the radiator) can be pressed against the surface of the bottle with the help of a spring strut mechanically fixed to the body of the microprocessor device or thermal insulator. Alternatively, the sensor can be placed on the brass strip 5 of FIG. 2. And the case itself can be mechanically mounted on the insulator 4, both outside and inside. It is enough that only the sensor was inside the thermal insulator, and the microprocessor device case was located outside. This will also slightly increase the accuracy of measurements, eliminating the thermal radiation of the microprocessor.

In the case of mounting on the neck, a large surface of the bottle will be available for cooling / heating the bottle with a temperature accumulator or air, which means that the process of changing the temperature of the liquid will proceed faster. And the best accuracy of measuring the temperature of the liquid in the bottle is achieved due to the smaller cross-sectional area of the glass of the bottle through which heat can pass from / to the external environment to / from the sensor and the greater the distance of the sensor from the cooler / heater: temperature or atmosphere battery. This reduces the effect of the cooler / heater on the sensor, and the “contribution” of the liquid to the sensor readings will be more significant.

If the said temperature accumulator is placed on top of the bottle in case of cooling and below in the case of heating, then placing the sensor on the neck of the bottle will also increase the accuracy of measuring the temperature of the liquid. Due to convection of the liquid in the middle of the bottle in height, there will be a liquid with a temperature closer to the average in the bottle, and the neck is placed just in the middle.

Claims (13)

1. Thermometer for a bottle containing: - temperature sensor; - a microprocessor device that receives data from said temperature sensor; - a holder securing the said sensor above or on the neck of the bottle and providing such a placement of the said sensor that the sensor is capable of sensing temperature values from a portion of the surface of the neck of the said bottle; characterized in that: - said sensor senses thermal energy, most of which comes from the neck portion of said bottle, which does not come into contact with a stopper plugging said bottle from inside the said bottle; - contains a thermally insulating device that prevents heat transfer from / to at least most of the outer surface of the neck of the bottle and said sensor / sensor, but does not prevent heat transfer from / to most of the outer surface of the said bottle as a whole. 2. A thermometer for a bottle according to claim 1, characterized in that it contains a device that prevents the movement of air from or into the aforementioned thermally insulating device. 3. A thermometer for a bottle according to claim 1, characterized in that it contains a pile serving as a heat insulator and / or said holder. 4. A thermometer for a bottle according to claim 2, characterized in that the said device, preventing the movement of air, contains a pile. 5. A thermometer for a bottle according to claim 1, characterized in that all the components of the said thermometer indicated in paragraph 1 have mechanical connections to each other for faster installation of the thermometer on the bottle. 6. A bottle thermometer according to claim 1, characterized in that said microprocessor device is located outside said thermally insulating device. 7. A bottle thermometer according to claim 1, characterized in that said thermally insulating device comprises foamed plastic.

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