RU178288U1 - Window type device - Google Patents

Abstract

The invention relates to self-contained windows with electric heating and window frames with heating devices specially designed for transparent or reflective surfaces (for example, window panes), namely to autonomous window-type heating devices. The technical result consists in increasing the reliability of a window-type battery by additionally built-in sensor for monitoring the charge level of the discharge and the dynamics of the batteries connected to the controller. The claimed result is achieved is a window-type device including a frame with a double-glazed window containing an outer glass of a double-glazed window connected to a means of converting light into electric current, which is configured to generate electrical energy from light incident on the outer glass of a double-glazed window, and an inner glass of a double-glazed window from incoming electrical energy, and the means of converting light into electric current and the inner glass of the glass packet are connected to the controller, to which the battery is switched on, and further comprises a sensor for monitoring the level of charge of the discharge and the dynamics of the batteries connected to the controller.

Description

The technical field to which the utility model relates.

The utility model relates to self-contained windows with electric heating and window frames with heating devices specially designed for transparent or reflective surfaces (for example, window panes), namely, to autonomous window-type heating devices.

State of the art

A window type device is known (patent RU 154157 U1, published on 08/20/2015), including a frame with a double-glazed window, comprising an outer glass of a double-glazed window, configured to generate electrical energy from light incident on it, connected to the inner glass of a double-glazed window, made with the possibility of heat generation from incoming electrical energy, and the outer glass of a double-glazed window is made in the form of at least one transparent photoelectric module and an inverter for converting light into electric current, p In fact, the transparent photoelectric module is made of a glass base, on top of which two layers of films are deposited: one film is made of amorphous silicon, and the second is a micro-transparent silicon film. Moreover, the frame additionally connected to the outer glass of the double-glazed window and the inner glass of the double-glazed window, the controller to which the battery is connected.

The disadvantage of this analogue is the premature failure of the battery, since the device does not have the technical ability to control the degree of charge-discharge of the battery, as well as analyze the dynamics of this process in real time.

Utility Model Disclosure

The technical result consists in increasing the reliability of the battery of a window type device, due to the additionally built-in sensor for monitoring the level of charge of the discharge and the dynamics of the batteries connected to the controller.

The claimed result is achieved by a window-type device, which includes a frame with a double-glazed window, containing the outer glass of the double-glazed window, connected to the means of converting light into electric current, which is configured to generate electrical energy from light incident on the outer glass of the double-glazed window, and the inner glass of the double-glazed window heat from incoming electrical energy, and a means of converting light into electric current and the inner glass of the glass are connected to the controller to which the battery is connected, and further comprises a sensor for monitoring the level of charge of the discharge and the dynamics of the batteries connected to the controller.

According to a utility model, the means for converting light into electric current is in the form of an inverter.

According to a utility model, a sensor for monitoring the level of charge of the discharge and the dynamics of the batteries is connected in addition to the battery.

According to a utility model, the outer glass of a double-glazed window is made in the form of at least one transparent photoelectric module, which is connected to an inverter for converting light into electric current.

According to a utility model, the sensor for monitoring the level of charge of the discharge and the dynamics of the batteries is equipped with a switch of control modes.

According to a utility model, it further comprises a control panel and a screen that are displayed on the outer surface of the window frame connected to the controller.

According to a utility model, it further comprises means for switching modes of using battery energy connected to the controller.

According to a utility model, it further comprises a socket connected to a means for switching modes of using battery energy.

According to a utility model, a means of converting light into electric current is connected in addition to the inner glass of the glass packet.

Brief Description of the Drawings

The essence of the utility model is illustrated by the figure, which shows the device window type left side view in section in a preferred embodiment of the claimed utility model.

Utility Model Implementation

The figure shows a window type device, which includes a frame 1 with a double-glazed window, containing the outer glass 3 of the double-glazed window connected to the means of converting light into electric current 6, which is configured to generate electrical energy from light incident on the outer glass 3 of the double-glazed window, and the inner glass 2 a double-glazed window made with the possibility of generating heat from the incoming electric energy, the means of converting light into electric current 6 and the inner glass 2 of the double-glazed window are connected a controller 4 connected to the battery 5, and further comprising a sensor monitoring the discharge power level and dynamics of batteries 7 is connected to the controller 4.

It should be noted that the inner glass 2 of the double-glazed window can be made according to the ThermoGlass technology, from high-strength tempered glass, on top of which a conductive coating is applied, on which electricity is supplied through wires.

In addition, in a preferred private embodiment of the claimed utility model, the outer glass 3 of the double-glazed window can be made in the form of at least one transparent photovoltaic module, which can be made using the well-known Vekag technology (which is used in civil and industrial construction of modern buildings and structures for glazing of conservatories, building facades, in the production of windows, fences, parking lots, billboards, awnings and in many other architectural projects) connected to an inverter for converting light into electric current, and the inverter itself, for example, can be connected to a window type device controller. Moreover, the transparent photovoltaic module is made of a glass base on top of which two layers of films are deposited, one amorphous silicon film that converts the visible part of the solar spectrum into electrical energy, and the second micro-transparent silicon film converts the sun energy of the invisible infrared spectrum, thus, the claimed design generates significantly more electricity, unlike analogs, and therefore it will be even more efficient to heat the inner glass of the double-glazed window and significant but accumulate more electric energy in the battery, which will affect the duration of heating.

In addition, in various embodiments, all structural elements (controller, battery, means for converting light into electric current, means for switching modes of using energy of batteries, etc.) of the claimed window type device can be fixed either inside the frame or on it.

The device operates in the preferred embodiment as follows.

Sunlight enters the outer glass 3 of the double-glazed window, which is converted through a means of converting light into electric current 6 into electric energy, with the help of which the controller 4 heats the inner glass 2 of the double-glazed window, while excess electric energy recharges the battery 5 throughout the daylight hours. All this time, the sensor for monitoring the charge level of the discharge and the dynamics of the batteries 7 transmits to the controller data on the degree of charge-discharge of the batteries or the battery, as well as the dynamics of this process in real time. After that, the controller 4 begins to control the periods of charging or discharging the battery 5 to maximize its life. The controller 4 can discharge the battery 5 by heating the inner glass 2 of the double-glazed window.

In a particular embodiment of the utility model, the battery or batteries of the claimed window type device are connected by an electric circuit to an external public network. In addition, a temperature sensor can be additionally connected to the controller 4 in another embodiment of the claimed window type device, with which the controller 4 can heat the glass of the insulating glass 2 of the double-glazed window to a certain set temperature.

The sensor for monitoring the charge level of the discharge and the dynamics of the batteries 7 can display the degree of charge-discharge of the batteries, as well as the dynamics of this process in real time.

In addition, in another private embodiment of the claimed utility model, the sensor for monitoring the level of charge of the discharge and the dynamics of the batteries 7 is equipped with a switch of control modes: percentage of charge-discharge; amount of energy, watts; operating time in the selected mode; time until the battery (accumulator) is fully charged in this mode of solar activity; on / off the device.

In another particular embodiment, the window type device further comprises a control panel and a screen that are displayed on the outer surface of the window system and are accessible to the user.

It should be noted that the claimed window type device may additionally contain, for example, means for switching the battery energy use modes fixed in the frame of the glass packet, connected to the controller and simultaneously to the public network. Thus, the means for switching modes of using energy of the batteries can transmit electric energy to the public network. In addition, in a particular embodiment, a socket for connecting electrical devices and devices (an air conditioner, a telephone, a computer, lighting devices, etc.) can be outputted to the inner surface of a window type device (window system) through a means of switching battery energy utilization modes. Thus, the controller through the indicated means of switching the modes of using energy of the batteries can quickly and quickly if necessary discharge the battery (for example, using household appliances), which will additionally affect the claimed technical result to increase the reliability of the battery of a window-type device, since it discharges the battery if necessary, it will be possible not only by heating the inner glass 2 of the double-glazed window, but also by consuming electrical energy connected to external home appliances.

Possible switching modes: public network; space heating by heating the inner glass; electrical devices; switch off; turn on.

At the connection to the public network, it is possible to install an electric energy meter transmitted to the public network.

Heat generation by the inner glass can be performed over its entire surface.

The frame can be made of wood, or aluminum, or polyvinyl chloride, or fiberglass, or steel.

The inner glass of the double-glazed window can be made of high-strength tempered glass, on top of which a conductive coating is applied.

Claims (9)

1. The device is a window type, including a frame with a double-glazed window, containing the outer glass of the double-glazed window, connected to the means of converting light into electric current, which is made with the possibility of generating electrical energy from light incident on the outer glass of the double-glazed window, and the inner glass of the double-glazed window heat from incoming electrical energy, and the means of converting light into electric current and the inner glass of the glass packet are connected to the controller to which is connected A battery is provided, characterized in that it further comprises a sensor for monitoring the level of charge of the discharge and the dynamics of the batteries connected to the controller. 2. The window type device according to claim 1, characterized in that the means for converting light into electric current is made in the form of an inverter. 3. The window type device according to claim 1, characterized in that the sensor for monitoring the level of charge of the discharge and the dynamics of the batteries is connected additionally to the battery. 4. The window type device according to claim 2, characterized in that the outer glass of the double-glazed window is made in the form of at least one transparent photoelectric module, which is connected to an inverter for converting light into electric current. 5. The window type device according to claim 1, characterized in that the sensor for monitoring the level of charge of the discharge and the dynamics of the batteries is equipped with a switch of control modes. 6. The window type device according to claim 1, characterized in that it further comprises a control panel and a screen that are displayed on the outer surface of the window frame connected to the controller. 7. The window type device according to claim 1, characterized in that it further comprises means for switching modes of using energy of the batteries, connected to the controller. 8. The window-type device according to claim 7, characterized in that it further comprises a socket connected to a means for switching modes of using energy of the batteries. 9. The window type device according to claim 1, characterized in that the means for converting light into electric current is connected in addition to the inner glass of the glass packet.

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