RU2590874C1 - Bottle warmer for baby food with possibility of temperature control - Google Patents

Abstract

FIELD: food industry.

SUBSTANCE: invention relates to a device for temperature control and sterilisation of baby food bottles. Heater for bottles of baby food with temperature control comprises a power supply, a control unit of microwave generator, at least one infrared sensor, a heating chamber provided with one end cap and closed at other end, with arranged inside drum, provided with an electric motor and adapted to be forced mixing of contents of bottle during heating, and heating and drum chamber further provided with through holes, at least one each, made so that when drum of drum opening rotation capable of periodically combined with through hole in chamber wall heating with infrared sensor located opposite said chamber opening with its outer side, so that rotation of drum during heating infrared radiation from bottle, respectively, can periodically fall on infrared sensor sensing zone, drum rotation axis is horizontal or at an angle to horizontal.

EFFECT: invention increases rate of heating while ensuring absence of local overheating and increase in accuracy of output at target temperature throughout volume of contents of bottle.

21 cl, 1 dwg

Description

FIELD OF TECHNOLOGY

The invention relates to devices for controlling the temperature and sterilization of products, and more specifically, to bottle warmers with baby food and sterilizers for such bottles.

BACKGROUND

Temperature measurement with infrared sensors, incl. pyroelectric sensors, it is known for a long time - there are patents that are more than 20 years old, for example. US 5567941 (MATSUSHITA ELECTRIC INDUSTRIAL CO., LTD, IPC G01J 1/04, publ. 10/22/1996). Infrared sensors are widely available in the electronics industry.

Also, technical solutions have long been known where an infrared radiation sensor (in particular a pyroelectric sensor) is used to control the temperature of objects heated in microwave ovens, for example. US 4347418 (MATSUSHITA ELECTRIC IND CO LTD, IPC Н05В 6/68, publ. 08.31.1982), MY116721 (SANYO ELECTRIC CO, IPC F24C 7/00, publ. 31.03.2004). The known technical solution is quite trivial, therefore, the number of patents in which it is applied is quite large.

The main disadvantages of analogues that use a microwave oven with an infrared radiation sensor to heat bottles with baby food are:

1) the need to manually enter the target temperature of the contents;

2) low accuracy of temperature measurement due to the remoteness of the sensor from the heated object (large heating chamber);

3) for a more uniform irradiation of a heated object in microwave ovens, as a rule, a rotating table is used that does not allow the heated object to be well positioned for accurate temperature measurement by an infrared radiation sensor;

4) due to the lack of forced mixing, the contents of the bottle are heated unevenly - the outer layer warms up more, which can lead to decomposition of nutrients, while the inner layer remains cold;

5) low accuracy of reaching the target temperature.

The target temperature in this description should be understood as entered by the user, or set by default, or corresponding to the selected heating mode, the value of the temperature of the contents of the bottle, upon reaching which (according to the measurement results) the heating stops.

On the open market, models of baby food bottle warmers are offered, in which they are heated using hot water or steam, for example, Philips electronic heater (http://www.philips.ru/c/avent-baby-preparing-for-feeding/ avent-digital-bottle-warmer-scf260_37 / prd /). In this model, the user needs to enter the volume, type, and initial temperature of the contents, based on which the processor automatically calculates the heating time required to reach the target temperature.

The main disadvantages of the known analogue are:

1) the need to manually enter the volume, type, and initial temperature of the contents, the exact values of which in some cases are not known to the user, which leads to an incorrect calculation of the heating time;

2) a choice of only three types of contents is proposed, for other types with different thermal conductivity and heat capacity, the heating time can be calculated incorrectly;

3) in addition to inconvenience for the user when entering the specified information, the probability of a user error when entering it (human factor) increases, which leads to an incorrect calculation of the heating time;

4) the device contains hot water, which can lead to burns, including for a child;

5) scale accumulates in the device, which changes the characteristics of heating;

6) due to the lack of forced mixing, the contents of the bottle are heated unevenly - the outer layer warms up more, which can lead to decomposition of nutrients, while the inner layer remains cold;

7) when calculating the heating time, the heat capacity and thermal conductivity of the bottle are not taken into account, which can lead to incorrect calculation of the heating time.

From the application US 20080121636 A1, a domestic microwave oven is known, equipped with an infrared sensor, which measures the temperature of a food container (including baby food bottles). This measurement is carried out just before the start of the heating of the container (bottle). For proper temperature measurement, the specified container (bottle) is placed in a special holder, which ensures its positioning relative to the sensor. The user is prompted to enter the mass or volume of food, as well as the target temperature. Based on these data, the time and power required to heat the contents to the target temperature are automatically calculated. Moreover, the specified holder can be equipped with a device that automatically measures the mass of the container with the contents.

The main disadvantages of this analogue are:

1) the need to manually enter the volume (mass) of the content (in some embodiments);

2) the need to manually enter the target temperature of the contents;

3) during automatic weighing of the bottle with the contents, the mass of the bottle itself is not taken into account, which can be comparable with the mass of the contents, which leads to incorrect calculation of the heating time;

4) different types of contents of the bottle can have significantly different thermal conductivity and heat capacity, which is not taken into account in calculating the heating time and leads to its incorrect calculation;

5) due to the lack of forced mixing, the contents of the bottle are heated unevenly - the outer layer warms up more, which can lead to the decomposition of nutrients, while the inner layer remains cold.

The closest analogue (prototype) is a microwave oven equipped with a processor (CN 103844916, HARBIN SAN NOT JIAMEI TECHNOLOGY DEVELOPMENT CO., LTD, IPC A47J 36/24, published 11.06.2014), containing a network plug (1), a special-purpose controller (2), a rotating platform (3), equipped with a bottle (4) for baby food, a microwave source (5), an IR temperature sensor (6), a microwave oven housing (7), a top cover (8), where the network The plug providing access to the power supply of the special-purpose controller (2) is a microwave power supply. The controller (2) is installed in the lower part of the body of the microwave oven (7) and is the control center of the entire microwave oven. A rotating platform (3) is installed in the center of the lower part of the microwave oven (7) and is rotatable during heating of the bottle with the nutrient mixture at a constant speed. A microwave radiation source (5) is installed in the housing (7) on the right side and is designed to heat the liquid contents of a milk bottle (4). An IR temperature sensor (6) is installed on the left side of the microwave oven housing (7) and is designed to measure the temperature of the liquid inside the bottle (4). The cover (8) is designed to close the housing (7) during heating and is made with the possibility of opening to place the bottle (4) in the inner part of the housing (8) on the platform (3). In this case, the controller (2) is configured to supply a signal to a microwave source to start heating and signal to stop heating when the temperature reaches 37 ° C, and maintain the temperature to obtain a product.

One of the disadvantages of the prototype is the lack of forced mixing of the contents of the bottle, which is why the device is not able to perform the assigned tasks efficiently, namely, to heat the contents of the bottle to 37 ° C in an acceptable time evenly and without overheating. In this case, the shutdown by the temperature sensor will occur before the average volume temperature of the contents reaches the target. For example, if you try to heat a glass of milk in a microwave, then the milk warms up very unevenly, which is noticeable even to the touch - you can burn on the walls of the glass, and in the center the milk remains cold. Baby mixes are even thicker, so for them the situation will be even worse in this regard. Frozen milk can also not be qualitatively heated without stirring.

Thus, the disadvantages of the prototype are:

1) a low heating rate, since the design of the device does not provide mixing of the contents of the bottle both in the volume of the surface layer and at a certain depth, therefore, in order to avoid local overheating of the surface layer of the contents of the bottle and to ensure that the temperature is equal to the volume of the bottle, it is necessary to maintain an average heating power of sufficiently low, which will increase the heating time;

2) the presence of local overheating, again due to the fact that the design of the device does not provide mixing of the contents of the bottle in volume, as a result of which a temperature difference will form between the surface layer of the contents and the contents at a certain depth;

3) low accuracy of reaching the target temperature, since the infrared radiation sensor in the device design provided is capable of measuring the temperature of the surface layer, and when heated, the surface layer of the contents of the bottle will always have a temperature higher than the contents at a certain depth.

SUMMARY OF THE INVENTION

The problem to which the invention is directed, is to create a new device for heating bottles with baby food, providing quick and uniform heating of the contents of the bottles, including the contents of the surface layer and contents at a certain depth, without local overheating, including higher temperatures that can lead to decomposition of useful substances in the content.

The technical result achieved by using the invention is to increase the heating rate while ensuring the absence of local overheating, including above temperatures that can lead to decomposition of useful substances in the contents, and improving the accuracy of reaching the target temperature in the entire volume of the contents of the bottle, including the contents surface layer and content in depth.

The task and the required technical result are achieved due to the fact that a new bottle warmer with baby food with temperature control, comprising a power supply, a control unit, a microwave generator, at least one infrared sensor, a heating chamber equipped with one end cap and closed from the other end, with located inside it means for rotating the bottle, equipped with an electric motor, where according to the invention, the means for rotating the bottle is a drum, made with the possibility of forced mixing of the contents of the bottle during the heating process, the heating chamber and the drum being additionally provided with through holes, at least one each, made in such a way that when the drum rotates, the drum opening can periodically be combined with the through hole in the wall of the heating chamber, this infrared radiation sensor is located opposite the specified camera hole on its outer side so that when the drum rotates during heating, the infrared red radiation from the bottle, respectively, is periodically able to hit the sensitive area of the infrared sensor, while the axis of rotation of the drum is located horizontally or at an angle to the horizontal, where the output of the power supply is connected to the input of the control unit, the outputs of which are connected to the microwave generator and electric motor, and the side surface of the drum is equipped with at least one element configured to change the angle of inclination of the axis of the bottle during rotation, which is a protrusion made, for example ep, in the form of ribs and / or spherical bulges, and / or recesses, and at least one hole is made, for example, in the form of a slot or slot, the drum itself and the elements for changing the axis of the bottle are made of dielectric material, and the axis of rotation the drum can be located at an angle of no more than 60 ° to the horizontal, while the hole in the heating chamber is equipped with a dielectric cap that transmits infrared radiation in a range that corresponds to the sensitivity band of the infrared radiation sensor, and prevents possible contamination of the sensitive area of the infrared sensor, which can be additionally equipped with a temperature sensor, for example, a thermocouple, or another pyrometric sensor that measures the temperature of the infrared sensor itself and / or its surrounding structural elements, and the means for rotating the bottle is additionally equipped with a synchronization device, the output of which is connected with the input of the control unit.

In an alternative embodiment, the heater is further provided with a device for cooling the contents of the heating chamber, the input of which is connected to the output of the control unit.

In yet another alternative embodiment of the invention, the heater is further provided with a water tray configured to sterilize the contents of the heating chamber with steam produced during the heating process.

In yet another alternative embodiment of the invention, the heater is further provided with a fan for cooling the magnetron of the microwave generator.

In yet another alternative embodiment of the invention, the heating chamber is provided with additional ventilation openings for the passage of air from the fan.

In yet another alternative embodiment of the invention, the heater is provided with an external additional housing.

In yet another alternative embodiment of the invention, the heater is further provided with an indicator of the set target and / or current temperature of the contents of the bottle, the input of which is connected to the output of the control unit, where, for example, LED panel, liquid crystal display or LED display are used as indicators.

In another alternative embodiment of the invention, the heater is further provided with at least one control element for changing the target temperature, made, for example, in the form of a touch panel, button, joystick or handle.

In yet another alternative embodiment of the invention, the heater is further provided with a sound emitter that provides audible signals about events during operation of the heater.

A significant difference of the invention is the constant mixing of the contents of the baby bottle during heating in the microwave field, which is optimally positioned relative to the infrared sensor for accurate temperature measurement, coupled with repeated measurements of the temperature of its surface during heating. The microwave field heats not only the surface layer, but also the contents at a certain depth, while constant mixing provides a slight temperature difference throughout the volume of the contents, which allows to increase the average heating power without the risk of overheating of certain areas of the contents, including above temperatures that can cause to the decomposition of useful substances in it. The increase in average power, in turn, allows you to proportionally reduce the heating time. At the same time, measurements taken together with mixing of the temperature of the surface of the bottle for the reason described above allow, with greater accuracy than in the prototype (without mixing), to determine the average temperature by the volume of the contents, which allows you to more accurately determine the moment to stop heating and, thereby, increase the accuracy reaching the target temperature.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be more clear from the description, which is not restrictive and given with reference to the accompanying drawing, in which:

In FIG. 1 - shows a General diagram of the device.

DETAILED DESCRIPTION OF THE INVENTION

The bottle 1 with the contents is placed horizontally (Fig. 1) or at an angle (not shown in the drawings) in the dielectric drum 2 with one or more holes 3, made, for example, in the form of slots or slots on its side surface. The drum 2 can be made in the form of a cylinder (Fig. 1) or a polyhedron (not shown in the drawings) or any other suitable shape. The specified drum 2 is connected by a shaft with an electric motor 4, which can also be equipped with a gear (not shown in the drawings), for example, with an electric motor used in domestic microwave ovens to rotate the table. The electric motor 4 provides the rotation of the drum 2 with a period from 0.3 to 30 seconds. At a higher speed, the contents are agitated and foamed, and at a lower speed, sufficiently effective mixing is not achieved. On the inner side of the drum 2 may be provided with at least one element configured to change the angle of inclination of the axis of the bottle during rotation, representing a recess (not shown) and / or protrusions made, for example, in the form of ribs (on not shown) and / or spherical bulges 5 (Fig. 1). These elements contribute to more intensive mixing of the contents of the bottle 1 in a direction along its longitudinal axis.

The drum 2 and the elements for changing the axis of the bottle 2 are made of dielectric material.

The axis of rotation of the drum can be located at an angle (not shown in the drawings), but not more than 60 ° to the horizontal, since at large angles, sufficient mixing of the contents of the bottle is not provided.

The drum 2 is placed in a cylindrical metal heating chamber 6 located horizontally (Fig. 1) or at an angle (not shown in the drawings), closed from one end, and provided with a metal cover (door) 7 from the other end, which can be fixed to the housing hinges 6 of the camera with the possibility of its opening by the user through which the bottle 1 is loaded inside. The camera 6 may have any possible shape that ensures proper functioning of the device, for example, the shape of a rectangular prism (not shown in the drawings it seemed). Microwave radiation from a microwave generator 8, for example, one of the standard magnetrons used in household microwave ovens, is introduced into said chamber 6, and at least one through hole 9 is provided in its side surface. The outside of the heating chamber 6 is near the through hole 9, the infrared radiation sensor 10 is located in such a way that when the drum 2 rotates at certain periods of time, the holes 3 (slots, slots) in the drum 2 are able to be opposite the holes 9 in the wall of the heating chamber 6, and thermal infrared radiation 11 from agrevaemoy bottle 1, respectively, can occasionally fall on the sensitive area sensor 10, the infrared radiation. This design of the chamber 6 and the drum 2, as well as the location of the through holes 3 and 8, ensure optimal positioning of the bottle relative to the infrared sensor to ensure accurate measurement and temperature control while continuously mixing the contents during heating, which allows to increase the heating rate and at the same time avoid the formation of the temperature difference between the surface layer of the contents of the bottle 1 and the contents at a certain depth, namely, to eliminate local overheating, i.e. when heated, the surface layer of the contents of the bottle 1 will always have the same temperature as the contents at a depth, therefore, the infrared sensor 10, measuring the temperature of the surface layer of the contents of the bottle, in fact, will give the actual temperature of the contents as a whole, thereby increasing accuracy the device reaches the target temperature.

The hole 9, through which infrared radiation 11 is supplied from the heating chamber 6 to the infrared radiation sensor 10, can be closed by a thin dielectric cover (not shown in the drawings), which transmits infrared radiation in a range that corresponds to the sensitivity band of the infrared radiation sensor 10, and which prevents possible contamination of the sensitive area of the infrared sensor 10. The hole 12 (Fig. 1), through which electromagnetic radiation from the microwave generator 8 is introduced into the heating chamber 9, can also be closed by a lid or lpachkom dielectric which avoids foreign objects and substances to the radiating pin magnetron.

The rotary drum 2 combines the functions of providing mixing of the contents of the bottle 1, its positioning relative to the infrared sensor 10, as well as the shutter function for infrared thermal radiation from the bottle 1.

The drum 1 may be additionally equipped with a synchronization device 13 connected to the control unit 14, which in the above periods of time generates an electrical signal - a sync pulse. The presence of a clock pulse allows, for example, to apply the well-known synchronous detection technique implemented in the control unit 14 to measure thermal radiation from a heated object by the infrared sensor 10. To minimize the influence of the microwave field directly on the infrared radiation sensor 10, according to a sync pulse, the control unit 14 can turn off the power of the microwave generator 8 during periods of time when the thermal radiation from the heated object is measured by the infrared radiation sensor 10. This avoids the influence of electromagnetic radiation from the microwave generator on the infrared sensor during the measurement, which can sometimes lead to measurement errors, and thereby further improve the accuracy of temperature measurement by the sensor 10. The synchronization device 13 can be a mechanical or magnetic switch driven in action by cams or magnets on an electric motor shaft. It is also possible to use optocouplers (not shown in the drawings), in this case, a shutter is fixed on the motor shaft.

The signals from the infrared sensor 10 and from the synchronization device 13 are sent to the control unit 14.

The input of the control unit 14 is connected to the output of the power supply (not shown in the drawings), equipped with a switch 15, with which the user can turn the heater on or off. The control unit 14 also supplies the signal and power to the microwave generator 8 and to the electric motor 4. In some embodiments of the invention, the control unit 14 may contain additional intermediate elements, for example, specific power units of elements, etc. (not shown in the drawings).

Due to the application of standard techniques known in the microwave technology, the heating chamber 6 with a cover (door) is designed to minimize microwave radiation into the surrounding space.

Using a clock pulse in the control unit 14, the widely known method of synchronously detecting a signal from an infrared sensor 10 is implemented. This method can significantly increase the accuracy of measuring a useful signal even in the presence of strong noise. To minimize the influence of the microwave field directly on the infrared radiation sensor 10, according to the clock pulse, the control unit 14 can turn off the power of the microwave generator during periods of time when the thermal radiation from the heated object is measured by the infrared radiation sensor. When the signal from the infrared sensor 10 reaches a certain level corresponding to a predetermined target temperature of the contents bottle (eg, close to a normal human body temperature of 36-37 ° C), the control unit 14 turns off the heating.

Thus, in the new design of the proposed heater, due to the continuous mixing of the contents of the bottle, which is optimally positioned throughout the entire mixing process relative to the sensor 10, the temperature is controlled more quickly and uniformly compared to the prototype, and therefore more accurate heating to the target temperature (36 -37 ° C) regardless of the initial temperature, volume, type, thermal conductivity, heat capacity of the contents and the bottle. Heating 100 ml takes about 50 s, i.e. 2.5 times faster than the fastest competitors (warmers for baby bottles), and without the risk of local overheating of the contents.

The heater is convenient to use, since it works completely in automatic mode, in view of which it can have only one button - on / off (in the preferred embodiment). The heater is also safe to use, since it does not contain hot water, heated parts. Overheating of the content, for example due to a user error, is not possible. The preset target temperature is safe for the child. At the same time, the heater provides gentle heating. It is not the surface that is heated, but the entire volume with forced mixing. The local temperature does not rise above temperatures that can lead to decomposition of useful substances in the contents, which allows you to save all the useful substances in baby food. At the same time, it is possible to work with frozen contents (for example, frozen donor breast milk). In frozen form, the danger of local overheating is also absent, because the temperature of the contents cannot rise above its melting point close to 0 ° C. When a liquid phase appears inside the bottle as a result of heating and thawing, it begins to mix, constantly touching the solid phase, which has a melting point, so local overheating is also excluded at this stage.

In addition, the heater can be equipped with limit switches (not shown in the drawings) that open the power supply circuit of the microwave generator 8 with the lid (door) open 7. The heater can also be equipped with a temperature sensor (thermal relay) (not shown in the drawings) that open the microwave power supply circuit -generator 8 when it overheats. These elements are not shown in the diagram, since they do not fundamentally change the operation of the heater, but are required by safety requirements for domestic microwave ovens.

Additionally, the heater may be equipped with a fan (not shown in the drawings) cooling the magnetron. The specified fan is also controlled by the control unit 14. Also, ventilation holes (not shown in the drawings) may be present in the walls of the heating chamber 6, through which the air flow from the fan enters and leaves the chamber 6. In this case, the air flow cools the walls of the chamber 6 and the rotating drum 2 to room temperature, which reduces their thermal radiation and further improves the accuracy of measuring the temperature directly of the bottle 1.

Additionally, the heater can be equipped with an external casing (housing), incl. metal (not shown in the drawings). Due to the application of standard techniques known in the microwave technology, the casing is designed to minimize microwave radiation into the surrounding space.

In addition to the infrared sensor 10, which registers radiation from a heated object, a temperature sensor (e.g., a thermocouple, or another pyrometric sensor) can be used that measures the temperature of the infrared sensor itself and / or its surrounding structural elements (not shown in the drawings). Based on this measured temperature, a correction is introduced to further improve the accuracy of measuring the temperature of bottle 1.

Additionally, the heater may be equipped with an indicator of the set target and / or current temperature of the bottle 1 (not shown in the drawings), for example, an LED panel, a liquid crystal display, LED-, or other display, which increases the usability of the heater.

Additionally, the heater can be equipped with controls (not shown in the drawings) that allow the user to change (for example, on the recommendation of a doctor) the target temperature previously set by the manufacturer, including touch panel, buttons, joystick, handle, etc.

In addition, the heater can be equipped with a sound emitter (not shown in the drawings) that provides audible signals about events during the operation of the heater, for example, about the start and / or end of heating.

Additionally, the heater may be equipped with a refrigerator (for example, a Peltier element with a fan for cooling its hot part), which provides cooling of the heating chamber together with its contents to a temperature, for example, from 0 to 10 ° C (not shown in the drawings). Power to the specified refrigerator is supplied from the control unit 14. This allows you to pre-prepare the bottle 1 with baby food, place it in the chamber 6, and store it there at low temperature for a long time, and if necessary, turn on the heating and warm it.

An additional thermal sensor (thermal relay) can also be used to prevent the cooling of chamber 6 below 0 ° C (not shown in the drawings). In this case, the heater is equipped with a control element, for example, a touch panel, button, joystick, handle, etc., to enable cooling mode. In this case, the control unit 14 is supplied with a special program, which, when the cooling mode is turned on, turns off the heating and rotation of the drum, and supplies power to the refrigerator. When the heating mode is turned on, the control unit 14 turns off the refrigerator and returns to normal operation. For more efficient cooling, the heating chamber 6 may be coated with a heat insulating material, for example, a porous polymer (not shown in the drawings). The cooling mode allows the user to pre-prepare baby food in a bottle 1, and store it in a heating chamber 6 at a low temperature, for example, overnight. This excludes the development of microorganisms in it, including pathogenic. If necessary, by pressing just one button, the heater switches to heating mode and within a short time (for example, 0.5-2 minutes, depending on the amount of contents), the user receives a bottle of 1 comfortable temperature (for example, 36-37 ° C).

Additionally, the heater may have a sterilizer mode. For this, a special removable water tray is provided in the lower part of the heating chamber 6 (not shown in the drawings), and openings for steam exit are provided in its upper part (not shown in the drawings). In this case, the heater is equipped with a control element, for example, a touch panel, button, joystick, handle, etc., to activate the sterilizer mode. Before activating the sterilizer mode, the user is required to place in the drum 2 products to be sterilized (bottle, pacifier, etc.) and pour from 20 to 100 ml of water into the indicated tray. Less water boils too quickly and does not provide high-quality sterilization, and more boils too long, while the quality of sterilization is no longer improving. In this case, the control unit 14 is supplied with a special program, which, when the sterilizer mode is switched on, supplies power to the microwave generator 8 for a certain time, sufficient for high-quality sterilization (from 2 to 4 minutes - generally accepted values for sterilizers for baby bottles). Microwave radiation heats the water, as a result of which it begins to boil, and the heating chamber 6 is filled with steam with a temperature of about 100 ° C, sterilizing objects placed in the drum 2. Excess steam exits through openings in the upper part of the heating chamber 6. After sterilization is completed, the pan with the remaining water is removed from the heating chamber 6. In order to avoid heating the outer surface of the heater, the heating chamber 6 may be coated with a heat insulating material, such as a porous polymer.

The heater operates as follows.

The user must turn on the heater in the mains, open the lid (door) 7, load the bottle 1 with contents inside the drum 2 and close the lid 7. The contents must have sufficient fluidity to flow to the bottom of the bottle 1 when the bottle is rotated. Also, the contents may be frozen, however, when thawing it should acquire the indicated fluidity. Microwave radiation from the microwave generator is introduced into the chamber 6, which produces heating of the indicated contents of the bottle. The drum 2 in the heating process rotates using an electric motor 4.

When the drum rotates, due to the fact that its axis of rotation is horizontal or at an angle to the horizontal, the bottle rolls in the drum and rotates around its axis, which ensures mixing of its contents. During rolling and rotation of the bottle 1 in the drum 2 in the liquid contents of the bottle, convection flows 16 arise, which mainly transfer heat in the directions perpendicular to the axis of rotation, roughly as shown schematically in FIG. 1. with a horizontal arrangement of the axis of rotation of the drum. Thus, the entire volume of liquid contents of the bottle 1 is predominantly involved in the mixing process, which is sufficient to ensure that the contents are quickly and uniformly heated in volume, including the contents of the surface layer and contents at a certain depth, without local overheating, including above temperatures that can lead to decomposition of useful substances in it. The microwave field heats only the contents of the bottle, but not its walls, not only the surface layer, but also the contents to a depth of several centimeters (depending on the properties of the contents). This ensures uniform heating of the entire volume of the contents, and the temperature of the outer surface of the bottle manages to equalize with the temperature of the contents.

In one alternative embodiment of the invention, the drum 2 may be provided with at least one element configured to change the angle of inclination of the axis of the bottle 1 during rotation, for example, by protrusions 5 (Fig. 1), and / or recesses (in the drawings not shown). During rotation of the drum 2 (Fig. 2), the bottle 1 periodically rolls through the protrusions 5 of the drum 2, which provides more intensive mixing of its contents. When rolling the bottle during rotation through the protrusion 5, the axis of the bottle changes the angle of inclination to the horizontal, due to which, in addition to the flows 16 indicated in the previous paragraph, additional convection flows 17 arise, which transfer heat mainly along the axis of the bottle. Thus, due to the combination of convection flows 16 and 17 arising simultaneously, the entire volume of the liquid contents of the bottle is involved in the mixing process. Together with forced mixing due to the location of the axis of rotation of the drum 2 horizontally or at an angle to the horizontal, this provides an additional uniform heating of the entire volume of the contents, and the temperature of the outer surface of the bottle 1 manages to equalize the temperature of the contents even faster.

And in the first and second embodiments of the invention described in the previous two paragraphs, this allows heating with much greater power than in the prototype without forced mixing without the risk of local overheating of the contents over temperatures that can lead to the decomposition of many useful milk proteins in the contents and other substances.

The control unit 14 supplies power to the microwave generator 8, the microwave radiation from which is introduced into the heating chamber 6. The microwave field heats only the contents of bottle 1, but not its walls, and not only the surface layer is heated, but also the contents to a depth of several centimeters, depending on the properties of the contents.

When the drum 2 is rotated at some points in time, the through holes 3 (slots, slots) in the drum 2 are opposite the through holes 9 in the wall of the heating chamber 6, and thermal infrared radiation from the heated bottle 1 falls on the sensitive area of the infrared radiation sensor 10. At these moments, the control unit 14, by a signal from the synchronization device 13, turns off the power of the microwave generator 8 in order to exclude the influence of electromagnetic microwave radiation on the infrared radiation sensor 10, which influence can sometimes lead to an error in temperature measurement. The signal from the infrared radiation sensor 10 enters the control unit 14, which, on the basis of the algorithm incorporated in it, makes a decision on the continuation, termination or adjustment of the heating power. If the temperature has not reached the target during the next measurement, the control unit 14 again performs a heating cycle. In this case, due to constant mixing, the average temperature of the contents of the bottle 1 will differ from the temperature of the wall of the bottle by no more than 2 ° C, while in the prototype (if there is no mixing), the temperature irregularities in the volume of the contents can reach tens of ° C. When, during the next measurement, the temperature reaches the set value, the control unit 14 no longer produces heating cycles and notifies the user of the end of the operation with a corresponding sound and / or light and / or other indication. After that, the user needs to open the lid 7 and remove the bottle 1 with the heated contents.

Thus, heating in comparison with the prototype occurs much (up to 2 times) faster, which is very important for bottle warmers. In this case, we can talk about a significant increase in the accuracy of reaching the target temperature, because due to constant mixing and the absence of temperature irregularities in the volume of contents, the measured temperature of the bottle wall with an accuracy of 2 ° C will be equal to the average temperature of its contents. It should be understood that the mentioned accuracy can be increased to a value of less than 2 ° C, for example, using certain techniques, for example, increasing the number of measurement cycles, varying the heating power, etc. Including the mentioned accuracy will be determined by the time spent on measurement. The more measurement cycles to do (one of the methods), the more accurately the temperature will be measured, for example, whether or not to measure “spurious” heating with an additional sensor, etc., including the measuring sensor itself, and the type of content.

It should be noted that the contents must have sufficient fluidity to flow into its lower part when the bottle is rotated. Also, the contents may be frozen (for example, frozen donor breast milk), however, when thawing, it must acquire the indicated fluidity.

In one of the alternative embodiments of the heater, providing for the adjustment of the target temperature, the user, using the appropriate controls (not shown), enters the desired target temperature. If the user does not do this, the default value is used.

Then, the user must press the on / off heating button, as a result, the work program starts to be executed in the control unit 14. If the cover 7 is open and its limit switches are in the appropriate positions, then no action is taken, otherwise, the control unit 14 supplies power to the electric motor 4, the rotating drum 2, and also to the cooling fan (not shown in the drawings) .

When the drum 2 rotates, the synchronization pulses from the synchronization device 13 begin to arrive at the control unit 14. In one of the embodiments of the heater, using the indicated clock pulses as a reference signal, the control unit 14 performs synchronous detection of the signal of the infrared radiation detector 10. In this case, constant or pulsed power is supplied to the microwave generator 8. In another implementation, power to the microwave generator 8 is supplied only at those time periods when infrared radiation from the bottle 1 does not reach the infrared radiation sensor 10, which eliminates the influence of the microwave field on him.

When an additional temperature sensor is used in an alternative embodiment of the invention (not shown in the drawings), the signal from it is registered by the control unit 14 and a corresponding correction is introduced into the useful signal.

If the user repeatedly presses the button (on the drawings not shown) to turn on / off the heating, or open the lid 7 of the chamber 6, or the temperature of the microwave generator 8 exceeds the maximum temperature, the control unit 14 immediately turns off the power to the microwave generator 8, electric motor 4 drum 2, and a fan.

If the signal from the infrared sensor 10 (after correction and / or synchronous detection) reaches a level corresponding to the set target temperature, the process stops, the power to the microwave generator 8, the electric motor 4 of the drum 2, and the fan is turned off. If the heater is equipped with a sound generator, an audible signal sounds about the end of heating.

If the function of the sterilizer is implemented in the heater, then for its use it is necessary to load 2 objects that need to be sterilized into the drum, pour 20 to 100 ml of water into the special heating chamber 6 in the heating chamber 6, close the lid 7, and press sterilization mode enable button. At the same time, the control unit 14 supplies power to the microwave generator 8 and the fan, for example, for 2-4 minutes, the generally accepted time for sterilizing baby bottles. If during the sterilization process the user presses the on / off button for sterilization mode, or opens the lid 7 of the chamber 6, or the temperature of the microwave generator 8 exceeds the maximum allowable temperature, the control unit 14 immediately turns off the power to the microwave generator 8 and the fan. After the specified time, the process stops, the power to the microwave generator 8 and the fan is turned off. If the heater is equipped with a sound generator, an audible signal is sent to indicate the end of sterilization. After the end of the process, the user must remove the pan with the remaining water.

If the function of the refrigerator is implemented in the heater, then for its use it is necessary to load bottle 1 with prepared baby food into drum 2, close the lid 7, and press the refrigerator mode enable button. In this case, the control unit 14 supplies power to the refrigerator (for example, the Peltier element) (not shown in the drawings), and to the fan cooling the hot part of the refrigerator. If the user then turns on the heating mode, the control unit 14 turns off the power of the refrigerator and switches to the normal heating mode described above.

Any bottle with any amount of any type of content can be placed in the heater (it must be fluid in an unfrozen state), with any initial temperature (including initially frozen).

For the operation of the heater, the user is not required to enter any data (in some embodiments, the target temperature can be entered at the request of the user), which eliminates the likelihood of error due to the human factor.

Due to forced mixing, the contents are heated evenly, while heating by the microwave field is carried out slowly enough so that the surface temperature of the bottle has time to equal the temperature of the contents, and the temperature is controlled by an infrared radiation sensor, by the signal from which the heating is turned off. This ensures that the exact target temperature is achieved in the entire volume of the content and eliminates the possibility of local overheating.

Although the present invention has been described in detail with examples of options that appear to be preferred, it must be remembered that these examples of the invention are provided only to illustrate the invention. This description should not be construed as limiting the scope of the invention, since the steps of the described methods and devices by specialists in the field of physics, electronics, signal processing, etc. can be amended to adapt them to specific devices or situations and not go out beyond the scope of the attached claims. Specialist in this field it is clear that within the scope of the invention, which is defined by the claims, various options and modifications are possible, including equivalent solutions.

Claims (21)

1. A heater for baby food bottles with temperature control, comprising a power supply, a control unit, a microwave generator, at least one infrared sensor, a heating chamber provided with a lid at one end and closed at the other end, with an inside her means for rotating the bottle, equipped with an electric motor, characterized in that the means for rotating the bottle is a drum made with the possibility of forced mixing of the contents of the bottle in the process of heating, and the heating chamber and the drum are additionally provided with through holes, at least one each, made in such a way that when the drum rotates, the drum hole can periodically be combined with the through hole in the wall of the heating chamber, while the infrared radiation sensor is located opposite the specified camera hole from the outside so that when the drum rotates during heating, infrared radiation from the bottle, respectively, is periodically able to get on the nuyu zone of the infrared sensor, wherein the drum rotation axis is positioned horizontally or at an angle to the horizontal. 2. The bottle heater according to claim 1, characterized in that the output of the power supply is connected to the input of the control unit, the outputs of which are connected to a microwave generator and an electric motor. 3. Bottle warmer according to claim 1, characterized in that the side surface of the drum is provided with at least one element configured to change the angle of inclination of the axis of the bottle during rotation. 4. Bottle warmer according to claim 3, characterized in that the elements for changing the angle of inclination of the axis of the bottle are protrusions and / or recesses. 5. The bottle warmer according to claim 4, characterized in that the protrusions are made, for example, in the form of ribs and / or spherical bulges. 6. The bottle warmer according to claim 1, characterized in that at least one hole is made, for example, in the form of a slot or slot. 7. Bottle warmer according to paragraphs. 1 and 3, characterized in that the drum and the elements for changing the axis of the bottle are made of dielectric material. 8. The bottle warmer according to claim 1, characterized in that the axis of rotation of the drum is located at an angle of not more than 60 ° to the horizontal. 9. The bottle heater according to claim 1, characterized in that the hole in the heating chamber is provided with a dielectric cap that transmits infrared radiation in a range that corresponds to the sensitivity band of the infrared sensor and prevents possible contamination of the sensitive area of the infrared sensor. 10. The bottle warmer according to claim 1, characterized in that the infrared sensor detecting radiation from the heated object can be additionally equipped with a temperature sensor, for example, a thermocouple, or another pyrometric sensor that measures the temperature of the infrared sensor itself and / or its structural elements. 11. Bottle warmer according to claim 1, characterized in that the means for rotating the bottle is further provided with a synchronization device, the output of which is connected to the input of the control unit. 12. Bottle warmer according to claim 1, characterized in that it is further provided with a device for cooling the contents of the heating chamber, the input of which is connected to the output of the control unit. 13. The bottle warmer according to claim 1, characterized in that it is further provided with a water tray configured to sterilize the contents of the heating chamber with steam produced during the heating process. 14. Bottle warmer according to claim 1, characterized in that it is additionally equipped with a fan for cooling the magnetron of the microwave generator. 15. The bottle warmer according to paragraphs. 1 and 14, characterized in that the heating chamber is equipped with additional ventilation openings for the passage of air from the fan. 16. The bottle warmer according to claim 1, characterized in that it is equipped with an external additional housing. 17. Bottle warmer according to claim 1, characterized in that it is further provided with an indicator of the set target and / or current temperature of the contents of the bottle, the input of which is connected to the output of the control unit. 18. The bottle warmer according to claim 17, wherein the indicators are, for example, an LED panel, a liquid crystal display or an LED display. 19. The bottle warmer according to claim 1, characterized in that it is further provided with at least one control for changing the target temperature. 20. The bottle warmer according to claim 19, characterized in that the control element is made, for example, in the form of a touch panel, button, joystick or handle. 21. The bottle warmer according to claim 1, characterized in that it is additionally equipped with a sound emitter that provides audible signals about events during the operation of the heater.