RU2709481C1 - Electric heating device - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to the field of electric engineering, and more specifically to the mobile heating device for personal electric heating. Proposed heating device implies its placement on any surface for comfortable sitting on it in various human habitats. Electric heating device comprises a resistive heating element fixedly fixed between two layers of fabric base. Resistive heating element is located between layers of fabric base in form of two symmetrically arranged relatively to longitudinal axis of meanders and is made in form of two separately connected insulated wires. Ends of the resistive heating element are connected to the power controller, which is connected to the flexible USB cable of the electric power connector, which in its turn is brought out of the electric heating device for power supply.EFFECT: higher efficiency of heating.15 cl, 3 dwg

Description

FIELD OF TECHNOLOGY

The invention relates to the field of electrical engineering, and more particularly to a mobile heating device for personal electric heating. The inventive heating device involves placing it on any surface for comfortable sitting on it in various human habitats.

BACKGROUND

In the process of human life, situations may arise when you need to warm up and bring the body into a comfortable state. However, due to various conditions and circumstances, it is not always possible to get warm, for example, when being outdoors, outdoors, staying at low temperatures, etc.

Today there are many electric heating devices, however, they are usually stationary, bulky and requiring power from the household electrical network. As a result, the known devices are not intended for stand-alone operation, that is, they are not mobile and convenient to use.

The prior art is known for electrically heated toilet seats. The seat contains a built-in electric heater, a cover, a casing covering the base, and a power cord. The device includes a heat reflector located inside the seat over the entire longitudinal section, a heat-insulating pad located below the heat reflector, a heat-resistant insulating tube and a temperature regulator located inside the base and connected to the power cord and electric heater (see RU 22023 U1, 10.03 .2002).

A disadvantage of the known device is its stationarity and not universality.

It is also known textile heating device containing conductive filaments (elements), which are introduced into the pre-formed textile structure in the form of ground threads symmetrically or asymmetrically spaced from each other. Resistive electric heating elements pass between opposite edge sections of the material, and conductive elements, for example, located along the edge sections, connect resistive electric heating elements with a constant household source of electrical energy (see RU 2222119 C2, 01.20.2004).

A disadvantage of the known device is the requirement for the constant availability of a household electrical circuit for power (lack of mobility of the device).

Also known from the prior art are mobile medical stretchers containing a frame of the main and head parts. In this case, the main part of the stretcher is equipped with flexible heating elements made in the form of multilayer electrically heated mats made of dacron threads with a resistive coating of silver placed on the inner surface of the main part of the medical stretcher. The heating mats are powered by a special mobile battery. To increase the efficiency of the heating elements, the composition of the heated mats includes a reflective layer made of aluminum film (see RU 142388 U1, 06.27.2014). The specified technical solution is taken as a prototype.

A disadvantage of the known solution is cumbersome, the need for a permanent special supply device, as well as a narrow scope.

SUMMARY OF THE INVENTION

The claimed technical solution is aimed at eliminating the disadvantages inherent in the prior art and the development of already known solutions.

The objective of the claimed technical solution is to create an absolutely mobile convenient universal device for personal electric heating in various places under various conditions (weather, surrounding, etc.).

The technical result achieved by using the claimed technical solution is to increase the heating efficiency by ensuring the mobility of the device and the uniform distribution of heat on its surface.

The claimed technical result is achieved due to the essential features characterizing an electric heating device containing a resistive heating element fixedly placed between two layers of the fabric base, while said resistive heating element is located between the layers of the fabric base in the form of two symmetrically arranged relative to the longitudinal axis of the meanders and made in the form of one insulated or two separately connected insulated wires, and the ends of the resistive the heating element is connected to a power controller, which is connected to a flexible USB cable of the electrical power connector, which in turn is taken outside the electric heating device to receive power.

Special cases of the implementation of the claimed technical solution are characterized by the following features.

The resistive heating element is located equidistant from the lateral edges of the layers of the fabric base.

The device further comprises a capacitive touch sensor connected to the power controller via a bus.

Said capacitive sensor is located between the branches of one of the meanders or between two meanders in the center of the longitudinal axis.

The device further comprises at least two load cells located between two meanders on the longitudinal axis and connected via a bus to the power controller.

The flexible cable of the electric power connector has an electric regulator with a light indicator.

The resistive heating element is sewn or glued to the layers of the fabric base.

Each layer of the fabric base from the inside is additionally equipped with a metal foil reinforced and covered with a protective dielectric film, between which the resistive heating element is located.

Resistive heating element wires have polymer heat-resistant insulation.

The device has a rectangular shape with side dimensions of 315 mm × 255 mm.

The device is configured to connect a USB power connector to any electrical device.

When connecting the USB power connector to a computing electrical device, the inventive device is designed to provide the user with the ability to control heating using the control software installed on said computing device.

In the case when the resistive heating element is made in the form of two separate insulated wires, said wires are interconnected at each end by a coupling for further connection with the power controller.

In the case when the resistive heating element is made in the form of two separate insulated wires, said wires are located at a distance S from each other.

The device is additionally made with the possibility of placement in an external case, which is made of PVC waterproof fabric, for example, such as "Oxford". Moreover, after placement in the external cover, the mentioned external cover is flashed around the perimeter.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an example of a first configuration of an electric heating device with a capacitive sensor.

FIG. 2 is an example configuration of an electric heating device with two load cells.

FIG. 3 is an example of a second configuration of an electric heating device with a capacitive sensor.

Designations on all figures are identical: 1 - resistive heating element; 2 - power controller; 3 - flexible cable; 4 - electrical power connector; 5 - capacitive sensor; 6 - tire; 7 - strain gauges.

DETAILED DESCRIPTION OF THE INVENTION

Below will be a description of exemplary embodiments of the claimed invention. However, the claimed invention is not limited to only these options for implementation. It will be apparent to those skilled in the art that any combination of features characterizing various embodiments of the inventive heating device is possible.

In FIG. 1 shows an electric heating device (heater) comprising a resistive heating element (1) fixedly disposed between two layers of a fabric base. Moreover, the resistive heating element is located between the layers of the fabric base in the form of two symmetrically arranged relative to the longitudinal axis of the meanders and is made in the form of one insulated or two separately connected insulated wires. Such placement allows you to evenly distribute the heat generated from the resistive heating element over the entire area of the heating device, which increases the efficiency of its use.

Moreover, in the case when the resistive heating element is made in the form of two separate insulated wires (not shown in the figures), said wires are interconnected at each end by a coupling for further connection with the power controller. Moreover, in this case, said wires are located next to each other at a predetermined distance S from each other.

The use of two insulated wires, for example, single-core, instead of one traditional wire with two insulated conductors of the same diameter, allows reducing the thickness of the heating device, since the height of the laid two wires will be less than the height of one wire with two insulated conductors of the same diameter. Thus, it becomes possible to make the mobile heating device thinner as a whole. The use of a thinner heater, in turn, is more practical, since it can be easily transported and located where it is convenient for the user. Due to the convenient and compact size of the heater, the user can use it more often and more efficiently. In this case, the wires of the heating element have a polymer heat-resistant insulation. When using fluoropolymers as insulation, the diameter of the outer insulation D of the heating wire may be limited to 1 mm.

In one of the private embodiments of the claimed device, each layer of the fabric base from the inside is additionally equipped with a metal foil reinforced and coated with a protective dielectric film, between which the resistive heating element is located. The foil layer of the fabric base can be made of aluminum, and the dielectric film for reinforcement can be made of lavsan.

The presence of reinforced metal foil in the design of the heating device allows to increase its mechanical strength while maintaining the necessary flexibility. Mechanical strength is a fairly important performance indicator. Metal foil can also be considered as part of the shielding element, which will reduce the insulation of the wires, which again helps to reduce the size of the wires themselves and the device as a whole.

The ends of the resistive heating element (1) are connected to a power controller (2), which is connected to a flexible cable (3) of a USB electric power connector (4), which, in turn, is moved outside the electric heating device to obtain power. In this case, the resistive heating element is located equidistant from the lateral edges of the layers of the fabric base.

The USB power connector (4) can be of any type and is designed to be connected to any suitable power source. The flexible cable (3) of the aforementioned connector (4) may have an electric controller with a light indicator to turn the heating on and off, as well as to adjust the amount of heating. In this case, the indicator light can signal the status of the heating device (on or off).

One of the distinguishing features of the inventive heating device is the presence of sensors in private versions. In the context of this application, two types of sensors are considered: a capacitive touch sensor and a strain gauge.

A capacitive touch sensor (5) is used to determine the presence and to further enable or disable heating, depending on this. It should be noted that these sensors can be located / placed in different positions relative to the resistive heating element. As shown in FIG. 1, a capacitive sensor (5) is located between the branches of one of the meanders (in this case, the lower one). In FIG. 3 you can see an example implementation of the inventive heating device, in which the sensor (5) is placed symmetrically between two meanders in the center of the longitudinal axis of the device. Moreover, these sensors in any of the described implementations are connected via a bus (6) to a power controller.

The load cells (7) shown in FIG. 2 are commonly used to measure strain size / magnitude, i.e. most often for weighing. In the context of this application, these sensors are also used to determine whether there is a deformation or not, due to which it is possible to draw a conclusion about the presence / presence of a person and, therefore, enable or disable heating, depending on the result. In FIG. 2 shows two load cells connected in series with each other via a bus (6). In an exemplary embodiment, load cells are located between two meanders on the longitudinal axis of the device and are connected via the same bus (6) to the power controller.

The insulated resistive heating element (1) can be sewn or glued to the layers of the fabric base, which will best fix its placement.

Based on the optimal size for ease of use of the claimed mobile heating device, taking into account the standard sizes of the most common chairs, chairs and seating in general, this device can be made in a rectangular shape with side sizes of 315 mm × 255 mm. It is these sizes that provide the most optimal convenience and comfort when using, storing and transporting the heater.

The claimed electric heating device is designed for the following electrical parameters: power - 8.5 W, voltage -5 V.

It should be noted that the inventive heater can receive power from various electrical devices by connecting a USB electric power connector, including personal ones with a USB port or USB connector, or the ability to connect a USB connector adapter. The most common power sources for the claimed device are laptops, portable batteries such as "Power Bank", stationary personal computers (PCs), as well as mobile phones and tablets. For example, when using a portable battery with a capacity of 5000 mAh (at a current of 2 A), the approximate operating time of the heater is 2-2.5 hours. Thus, the ability to use the device anywhere increases the efficiency of its use by providing mobility.

Currently, so-called “smart” devices that can be controlled from mobile computing devices are becoming increasingly popular. It is very convenient and visual for the user. In connection with this technical trend, the claimed technical solution also has the ability to control from a computing device.

Namely, in the case of receiving power from any computing device, for example, such as a laptop, PC or mobile phone, it is possible for the user to control the heating of the claimed device using special control software pre-installed on the said computing device. The software is used to regulate or smoothly change the heating value, by regulating the supply of the supply voltage to the resistive heating element, which in turn increases the usability of the heater for the user.

In addition, in another private embodiment, the use of special software to control heating, provided that it is connected to a laptop or PC and the heater is under the user, can convert the claimed electric heating device into a signaling device, indicating, for example, one or the other event.

However, the availability of special software is not a prerequisite for the operation of the heating device. The heater will perform its main heating function without software in standard operating mode.

Recently, people increasingly prefer to work with a laptop in the fresh air outdoors. In the evening, when the temperature begins to drop, working in the air may begin to cause some discomfort. In this case, the user who has the described electric heating device with him can place it on the surface of a bench or bench, or on a plaid, sit on it, connect it via a USB connector to a laptop, configure the comfort speed and heating temperature through pre-installed software on the laptop and continue work in more comfortable conditions.

In addition, the described design of the claimed heating device makes it effective and relevant almost anywhere in various weather conditions.

At the same time, the claimed heating device is made with the possibility of placement in a special external cover. Mentioned external cover may be made of PVC waterproof fabric, for example, such as "Oxford", which allows the use of the claimed device in various weather and domestic conditions.

An external cover with a heating device located inside can be stitched around the perimeter, which will make the cover and device a single flexible, non-separable design. At the same time, to satisfy various preferences of users, the cover can be of different colors (plain or with drawings).

It should be noted that certain dimensions, flexibility and material of the outer cover make the claimed heater universal in use, as well as convenient in operation and storage. Moreover, the flexibility of the heating device allows you to place it on the surface of any shape, which also increases the user’s convenience during its operation.

Although this technical solution has been described in detail in order to illustrate the currently most necessary and preferred embodiments of the heating device, it should be understood that the present invention is not limited to the disclosed embodiments and, moreover, is intended to modify and various other combinations of features from the described embodiments. For example, it should be understood that the present invention assumes that, to the extent possible, one or more features of any embodiment may be combined with another one or more features of any other embodiment.

Claims (17)

1. An electric heating device comprising a resistive heating element fixedly placed between two layers of a fabric base, characterized in that: said resistive heating element is located between the layers of the fabric base in the form of two symmetrically arranged relative to the longitudinal axis of the meanders and made in the form of two separately connected insulated wires, moreover, the ends of the resistive heating element are connected to a power controller, which is connected to a flexible USB cable of the electric power connector, which in turn is moved outside the electric heating device to obtain power. 2. The device according to claim 1, characterized in that the resistive heating element is located equidistant from the lateral edges of the layers of the fabric base. 3. The device according to claim 1, characterized in that it further comprises a capacitive touch sensor connected to the power controller via a bus. 4. The device according to p. 3, characterized in that the said capacitive touch sensor is located between the branches of one of the meanders. 5. The device according to p. 3, characterized in that the said capacitive touch sensor is located between two meanders in the center of the longitudinal axis. 6. The device according to claim 1, characterized in that it further comprises at least two load cells located between two meanders on the longitudinal axis and connected via a bus to the power controller. 7. The device according to claim 1, characterized in that the flexible cable of the electric power connector has an electric regulator with a light indicator. 8. The device according to claim 1, characterized in that the resistive heating element is sewn or glued to the layers of the fabric base. 9. The device according to claim 1, characterized in that each layer of the fabric base on the inside is additionally equipped with a metal foil reinforced and covered with a protective dielectric film, between which a resistive heating element is located. 10. The device according to p. 1, characterized in that the wires of the resistive heating element have a polymer heat-resistant insulation. 11. The device according to claim 1, characterized in that it has a rectangular shape with side dimensions of 315 mm x 255 mm. 12. The device according to p. 1, characterized in that it is configured to connect a USB power connector to any electrical device. 13. The device according to p. 12, characterized in that when connecting the USB power connector to a computing electrical device, it is possible for a user to control the heating by means of control software installed on said computing device. 14. The device according to any one of paragraphs. 1-15, additionally made with the possibility of placement in an external cover, which is made of PVC waterproof fabric, for example, such as "Oxford". 15. The device according to p. 16, characterized in that after being placed in an external cover, said external cover is stitched around the perimeter.

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