RU2844223C1 - Plenum ventilation device - Google Patents

Abstract

FIELD: air conditioning and ventilation.

SUBSTANCE: invention relates to air conditioning and ventilation, namely to plenum ventilation devices, and can be used for ventilation of residential and non-residential premises. In the proposed plenum ventilation device, the nozzle has a regular aerodynamic shape, the device head on the rear side contains built-in magnets for attachment to the mounting panel, printed circuit board includes spring contacts and wireless data transfer channel; mounting panel is made of metal and includes contact pads for connection of spring contacts.

EFFECT: design of the proposed plenum ventilation device provides improvement of its operational properties due to the fact that it makes it possible to easily access and replace the filter inside the air duct, reduce formation of frost in the area of the air outlet from the nozzle of the head in cold weather and enable control of operation of the device using wireless data transmission technology.

15 cl, 4 dwg

Description

The invention relates to the field of air conditioning and ventilation, namely to supply ventilation devices, and can be used for ventilation of residential and non-residential premises.

The state of the art widely presents supply ventilation devices of various designs, installed in a ventilation duct in the wall of a room or building: technical solutions under Russian patents for utility models No. 80923, 66488, 178462, 222712, 220495, 204494, 210001 and inventions No. 2744623, 2194222. The common basic design elements of these devices are, as a rule, an air duct with thermal insulation inside the ventilation duct in the wall of a room or building, an external ventilation grille attached to the air duct and a head (housing) inside the room with an opening (openings) for air outlet and an adjustable damper. Also, depending on the device, its design may additionally contain a filter of one or another cleaning class in the head or air duct, a supply fan, an electronic control unit, a temperature sensor. More expensive and energy-intensive devices may also contain a heating element.

Some supply ventilation devices use magnets to fix the flap (Russian patent for utility model No. 224215), to attach and replace the dust collector (foreign patent for invention No. CN 210373956 U), to attach the filter plate to the body (foreign patent for invention No. CN 214148234 U). In the solution for foreign patent No. JP 2001091004 A, a magnet, self-adhesive tape with a double coating, a fastening screw or a clamp can act as a fastener for the head to the ventilation opening.

As a result, based on the combination of essential features, the technical solution "COMPACT SUPPLY VENTILATION SYSTEM (THE DEVICE AS A WHOLE), A DEVICE FOR FORCED AIR SUPPLY AND A VENTILATION GRILLE (INDEPENDENT PARTS OF THE DEVICE)" was selected as a prototype under Russian patent for invention No. 2708105 (priority date 21.11.2018, publication date 04.12.2019). The supply ventilation system is characterized by the fact that it consists of an inlet grille, an air duct with a filter installed inside and a forced air supply device, which in turn consists of a housing made of a decorative panel and a supporting panel with a seat, a snail containing a main housing adjacent to the housing seat and a cover, a radial fan fixed inside the snail, a damper, an electronics unit, a heater, whereby a heat-insulating material is applied to the damper, and a temperature sensor is installed at the outlet of the snail.

The disadvantage of the prototype is the difficulty of replacing the corrugated filter inside the air duct, since this requires disassembling and removing the entire, rather complex in its design, forced air supply device (including the decorative panel, snail, fan, damper, outlet grille, electronics unit, supporting panel, its seat and heater).

The purpose of the claimed invention is to propose a supply ventilation device, the design of which allows easy access and replacement of the filter inside the air duct, as well as to reduce the formation of frost in the area of the air outlet from the head nozzle in cold weather and to ensure control of the device using Wi-Fi.

The stated goal is achieved by the fact that in the proposed supply ventilation device the nozzle for air outlet is made of the correct aerodynamic shape, the head of the device on the rear side contains built-in magnets for fastening to the mounting panel and spring contacts, the mounting panel is made of metal and contains contact pads for connecting spring contacts, and the printed circuit board of the device contains a wireless data transmission channel.

Accordingly, the technical result of the claimed technical solution of the supply ventilation device is as follows. The design of the proposed supply ventilation device ensures improvement of its operational properties due to the fact that it allows easy access and replacement of the filter inside the air duct, reduces the formation of frost in the area of the air outlet from the nozzle of the head in cold weather and ensures control of the device using wireless data transmission technology.

The technical result is achieved by the fact that the proposed supply ventilation device contains:

an indoor head unit with an air outlet nozzle at the top, a vent for air intake from the duct at the rear, a supply fan with a motor, an automatic adjustable insulated nozzle flap with a stepper motor and a printed circuit board with a controller, a temperature sensor, control buttons, a power supply,

a mounting panel attached to a ventilation duct in the wall of the room with a ventilation hole for attaching the head of the device to it,

an air duct located inside a ventilation duct in the wall of a room with thermal insulation and a filter inside,

an external ventilation grille attached to the air duct,

characterized in that the nozzle is made of a regular aerodynamic shape, the head of the device on the back side contains built-in magnets for fastening to the mounting panel, the printed circuit board contains spring contacts and a wireless data transmission channel, the mounting panel is made of metal and contains contact pads for connecting spring contacts.

The device can also be equipped with a class G2 filter.

The device can also be equipped with a G4 class filter.

The device can also be equipped with a class F5 filter.

The device can also be equipped with a class F6 filter.

The device can also be equipped with a class F7 filter.

The controller can also be designed with the ability to regulate the fan speed.

The device may also contain a remote control.

Also, the supply ventilation device may contain a sealing gasket on the ventilation opening of the device head.

The supply ventilation device may also contain a plastic ring that passes through the ventilation openings of the device head and the mounting panel and is placed in the air duct.

The mounting panel may also contain a heat-insulating gasket on the back side.

Also, the wireless data transmission channel can be designed with the ability to transmit data using Wi-Fi technology.

Also, the wireless data transmission channel can be designed with the ability to transmit data using Bluetooth technology.

Also, the wireless data transmission channel can be designed with the ability to transmit data using WiMAX technology.

Also, the wireless data transmission channel can be designed with the ability to transmit data using UWB technology.

The claimed technical solution is illustrated by an exploded schematic representation of the supply ventilation device as a whole (Figures 1, 2) and the head of the device separately (Figures 3, 4), where 1 is the head of the device, 2 is an air outlet nozzle, 3 is a ventilation hole on the rear side of the head, 4 is a supply fan with a motor, 5 is an automatic adjustable insulated nozzle damper, 6 is a stepper motor of the damper, 7 is a printed circuit board, 8 is a temperature sensor, 9 is control buttons, 10 is a power supply unit, 11 is built-in magnets, 12 is spring contacts, 13 is a mounting panel with a ventilation hole, 14 is a heat-insulating gasket on the rear side of the mounting panel, 15 is a sealing gasket, 16 is a plastic ring, 17 is an air duct with heat insulation, 18 is an external ventilation grille, 19 - socket, 20 - air outlet area from the nozzle, 21 - printed circuit board for contact pads for connecting spring contacts.

In order to achieve the technical result, the invention can be implemented in the following preferred manner with references to exploded schematic images of the supply ventilation device as a whole (Figures 1, 2) and the head of the device separately (Figures 3, 4). The schematic images are of an exclusively explanatory illustrative nature, the shape, proportions of the device, composition, appearance and mutual arrangement of its elements may differ from those shown in the images, but not go beyond the scope of the formula. It should be noted that the presented example of the implementation of the supply ventilation device does not exclude other methods of implementation within the framework of the claimed formula and in no way limits the scope of legal protection specified in independent claim 1 of the formula.

Also, the terms and concepts used in the formula and description may be understood as their synonyms, for example, the head of the device 1 is also understood as the body of the device, the nozzle 2 is understood as an opening, the damper 5 is understood as a valve, the mounting panel 13 is understood as a supporting panel, etc.

The proposed supply ventilation device is installed as follows. A ventilation duct is drilled in the wall of a room or building using a manual diamond drilling rig (not shown in the images). Then, the air duct 17 for the ventilation duct is insulated to prevent it from freezing in cold weather and an external ventilation grille 18 is attached to it. Then, the air duct with thermal insulation 17 and an external ventilation grille 18 is inserted into the ventilation duct. Next, a filter is placed in the air duct (not shown in the images). The filter can be made of classes G2, G4, F5, F6, F7.

Next, the mounting panel 13 is attached to the ventilation duct through the heat-insulating gasket 14 in such a way that the ventilation opening of the mounting panel 13 coincides with the opening of the ventilation duct. The mounting panel 13 is intended for attaching the head of the device 1 to it, is made of metal and contains contact pads (not shown in the images) connected to the power supply network and located on the printed circuit board 21 for connecting the spring contacts 12 on the printed circuit board 7 of the head of the device 1.

Then the head of the device 1 is attached with its back side to the metal mounting panel 13 using the built-in magnets 11 in such a way that the ventilation hole 3 for air intake of the head of the device 1 coincides with the ventilation hole of the mounting panel 13. In this case, the spring contacts 12 on the printed circuit board 7 of the head 1 are positioned and connected to the contact pads on the mounting panel 13. The contact pads on the mounting panel are connected to the main power supply network of the room or building. The supply ventilation device is installed and ready for operation.

The supply ventilation device operates as follows. After connecting the contact pads on the mounting panel 13 to the main power supply network of the room or building using the socket 19, the current flows through the spring contacts 12 and the power supply unit 10 on the printed circuit board 7 of the head 1 to the supply fan motor 4, the stepper motor 6 of the damper 5 located inside the head 1, as well as the controller (not shown in the images), the temperature sensor 8, the control buttons 9 and the wireless data transmission channel (not shown in the images) located on the printed circuit board 7. The controller controls the operation of the supply fan motor 4, the stepper motor of the damper 6, is electrically connected to the device operation control buttons 9, the temperature sensor 8 and the wireless data transmission channel. The wireless data transmission channel can be designed with the ability to transmit data using Wi-Fi, Bluetooth, WiMAX or UWB technologies. As a result, upon receiving the corresponding command via control button 9, remote control (not shown in the images) or via Wi-Fi, Bluetooth, WiMAX or UWB network to turn on the device, the controller connects the power supply circuit to supply current to the motor of the supply fan 4, which begins to operate and draw outside air from the air duct 17 in the ventilation channel through the nozzle 2 in the upper part of the head 1 into the room or building. In this case, the controller can be programmed for several speeds of fan 4, which can be switched using the control button on the device 9, remote control or Wi-Fi, Bluetooth, WiMAX or UWB network. The controller also receives information from the temperature sensor 8, which measures the temperature in the room or building. If the air temperature decreases, the controller can automatically reduce the speed of the fan 4, disconnect the power supply circuit to stop the current supply to the fan motor 4 to turn it off, or turn on the stepper motor 6 of the damper 5 to completely close the nozzle 2. If the air temperature increases, the controller can automatically connect the power supply circuit to supply current to the motor of the supply fan 4 to turn it on, increase the speed of the fan 4, or turn on the stepper motor 6 of the sealed damper 5 to open the nozzle 2. You can also turn on the stepper motor 4 to open/close the damper 5 using the control button 9 on the head of the device 1. In this case, the damper is insulated 5, which acts as additional insulation for the entire head 1, which prevents condensation from forming or the device from freezing as a whole.

The air coming from outside the room or building and pumped by the supply fan 4 through the ventilation grille 18, the filter in the air duct 17, the ventilation opening in the mounting panel 13 and the head 3 passes through the nozzle 2 located in the upper part of the head 1. In this case, the nozzle 2 is made of the correct aerodynamic shape and without lamellas, which prevents or reduces the formation of frost in the area of the air outlet from the nozzle of the head 20 in cold weather, and also the air flow directed precisely upwards allows for more efficient mixing with the warm air layers under the ceiling. The reduction in the formation of frost in the area of the air outlet from the nozzle of the head 20 in cold weather due to the correct aerodynamic shape of the nozzle is confirmed by the practical use of the device with a nozzle 2 of this shape on the head 1.

In this case, the supply ventilation device may contain a sealing gasket 15 on the ventilation opening 3 of the head of the device 1, intended for a tighter, hermetic connection of the head of the device 1 to the mounting panel 13. Also, the supply ventilation device may contain a plastic ring 16 passing through the ventilation openings of the head of the device and the mounting panel and placed in the air duct, which prevents the leakage of air passing through the air duct 17 and the ventilation openings of the head of the device 3 and the mounting panel 13 out into the room, i.e. improves the tightness of the device as a whole.

During operation of the device, the filter located inside the air duct 17, as in all other supply ventilation devices, periodically requires replacement. Unlike the prototype and other similar devices, in the presented solution, the head 1 is attached to the metal mounting panel 13 using built-in magnets 11. And to replace the filter inside the air duct 17 in the ventilation channel, it is enough to remove the head 1 from the mounting panel 13 with a small force in one movement and gain access to the air duct 17 with the filter inside. In this case, it is not necessary to disassemble the head/housing 1 of the device. After replacing the filter, you can also easily reattach the head 1 to the mounting panel 13.

The ability to connect the device via a wireless data transmission channel to a Wi-Fi network, as well as Bluetooth, WiMAX or UWB, provides the ability to control the operation of the device, turn it on or off, adjust the speed of the fan 4, from anywhere using a special mobile application on a smartphone.

Thus, the distinctive features of the proposed supply ventilation device allow achieving the stated technical result - ensuring the improvement of its operational properties due to the fact that the design of the device allows easy access and replacement of the filter inside the air duct, reducing the formation of frost in the area of the air outlet from the nozzle in cold weather and ensuring control of the device using wireless data transmission technology.

The proposed invention of a supply ventilation device is currently being produced by the applicant.

Claims (20)

1. A supply ventilation device characterized by the fact that it contains: an indoor head unit with an air outlet nozzle at the top, a vent for air intake from the duct at the rear, a supply fan with a motor, an automatic adjustable insulated nozzle flap with a stepper motor and a printed circuit board with a controller, a temperature sensor, control buttons, a power supply, a mounting panel attached to a ventilation duct in the wall of the room with a ventilation hole for attaching the head of the device to it, an air duct located inside a ventilation duct in the wall of a room with thermal insulation and a filter inside, an external ventilation grille attached to the air duct, characterized in that the nozzle is made of a regular aerodynamic shape, the head of the device on the back side contains built-in magnets for fastening to the mounting panel, the printed circuit board contains spring contacts and a wireless data transmission channel, the mounting panel is made of metal and contains contact pads for connecting spring contacts. 2. A supply ventilation device according to paragraph 1, characterized in that the device is made with a class G2 filter. 3. A supply ventilation device according to paragraph 1, characterized in that the device is made with a class G4 filter. 4. A supply ventilation device according to paragraph 1, characterized in that the device is made with a class F5 filter. 5. A supply ventilation device according to paragraph 1, characterized in that the device is made with a class F6 filter. 6. A supply ventilation device according to paragraph 1, characterized in that the device is made with a class F7 filter. 7. A supply ventilation device according to item 1, characterized in that the controller is designed with the ability to regulate the operating speed of the fan. 8. A supply ventilation device according to paragraph 1, characterized in that the device contains a remote control. 9. The supply ventilation device according to paragraph 1, characterized in that the supply ventilation device contains a sealing gasket on the ventilation opening of the head of the device. 10. A supply ventilation device according to paragraph 1, characterized in that the device contains a plastic ring passing through the ventilation openings of the head of the device and the mounting panel and placed in the air duct. 11. A supply ventilation device according to paragraph 1, characterized in that the mounting panel contains a heat-insulating gasket on the rear side. 12. A supply ventilation device according to item 1, characterized in that the wireless data transmission channel is designed with the ability to transmit data using Wi-Fi technology. 13. A supply ventilation device according to item 1, characterized in that the wireless data transmission channel is designed with the ability to transmit data using Bluetooth technology. 14. A supply ventilation device according to item 1, characterized in that the wireless data transmission channel is designed with the ability to transmit data using WiMAX technology. 15. A supply ventilation device according to paragraph 1, characterized in that the wireless data transmission channel is designed with the ability to transmit data using UWB technology.