RU2512073C1 - Air distributor - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention relates to air ventilation and conditioning. This process is performed in an automatic mode. Reduction of range of inlet jets is provided by a diffuser available at the device air outlet. Reduction of differential temperature between inlet air and room air is provided due to ejection of the room air to an air distributor casing, where the same air is swirled in the same direction as the air supplied from a conditioning system, which creates negative pressure in upper internal part of the casing, thus providing ejection of the room air; with that, amount of the ejected room air is controlled rather smoothly due to design features of a drive of a damper installed in the air duct through which the room air is supplied (sucked). Both air flows are mixed in the air distributor casing. Amount of the air supplied from the conditioning system and the ejected room air is controlled by dampers equipped with actuators receiving signals from temperature and air flow rate controls, to which temperature and air flow sensors are connected, which are installed at the air distributor air outlet.

EFFECT: device allows not only reducing the range of inlet jets in a room, but also reducing differential temperature between inlet air and room air.

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Description

The invention relates to air conditioning and ventilation systems and can be used in rooms for various purposes.

Known air distributor (RF patent No. 2250419, 2005), containing a diffuser housing with exhaust holes at its outlet, attached to the duct using a cylindrical inlet pipe, made on the surface of the latter ejection windows, an elastic cuff that can be moved along the ejector windows, installed in the inlet pipe there is a confuser insert, the bottom of the case has a spherical shape, convex inside the case and is equipped with a round hole, a septum is placed concentrically on the bottom along Orme, similar to the bottom having openings to the channels for the passage of air, in which air zakruchivateli installed.

The disadvantage of such an air distributor is:

- lack of structural elements that allow you to use the automatic control of the ejection of the amount of air from the room into the air distributor.

Known centrifugal air distributor design V.M. Elterman, cited in the book of this author "Ventilation of chemical industries", Moscow, "Chemistry", 1980, pp. 32-36 - the closest analogue.

The air distributor contains a cylindrical casing with an air intake slit made on its surface and a diffuser fixed in one of the ends of the casing, and the opposite end, near which the air intake slit is made, is plugged, a movable cylindrical pipe is coaxially inserted into the casing to control the air flow through the air distributor.

The disadvantage of such an air distributor is:

- the impossibility of reducing and regulating the temperature difference between the supply air and the room air; the inability to regulate the mentioned temperature difference in the automatic mode due to the lack of structural elements that allow air to be mixed into the supply air from the room.

The aim of the invention is the creation of an air distributor that allows you to mix with the supply air passing through the air distributor, the air from the room (recirculated air) to reduce the temperature difference between the supply air and the room air and to carry out this process in automatic mode, providing smooth mixing of the amount of air from the room into air distributor.

This goal is achieved due to the fact that the air distributor containing a cylindrical casing with a diffuser, mounted on the edges of the outlet opening of the casing and one of its ends and muffled by the opposite end, near the muffled end of the casing has an air inlet slot to which a cylindrical duct is connected tangentially relative to the surface of the casing, communicated with the room, the inlet of the duct is equipped with a flange, the duct is equipped with a flap made in the form of a flat cylinder, in the center a threaded hole is made, the corresponding thread is cut on an axis along which the shutter can move along the thread, the axis is fixed at one end in a sleeve mounted inside the duct coaxially with the latter and attached to the duct with rods, the plane of the shutter (cylinder base) facing the duct flange , is equipped with a sealing gasket on the edge, and a friction material tape is fixed on the side surface of the shutter, while the end of the shutter is in close contact with the side surface of the disc, fixed on and the actuator shaft, thus forming a friction disk-damper pair, and the actuator is electrically connected to a temperature controller, to which an air temperature sensor is connected, located at the air outlet from the diffuser; below the muffled end of the casing on the diametrically opposite side from the air intake slit, made near the muffled end of the casing, another air slit is made to which a cylindrical duct connected to the conditioning system is connected tangentially to the surface of the casing, connected to the air conditioning system, the duct is provided with a rotary damper, equipped with an actuator, to which the air flow regulator is electrically connected, and the date is connected to the regulator an air flow meter installed at the air outlet from the diffuser, while the location of both air intake slots to the casing ensures that the air flows coming from them in one direction inside the casing.

This design of the air distributor allows mixing air from the room to the supply air, reducing the temperature difference between the supply air and the room air, and this process is carried out automatically. At the same time, the friction pair “disk-damper” allows mixing air from the room to the air from the air conditioning system quite smoothly due to the smooth movement of the damper. At the same time, the design of the air distributor provides intensive mixing of the swirling and in one direction inside the casing supply jets from the air conditioning system and ejected air jets from the room, and after the swirling jets exit through the diffuser, the jets reduce their range (In accordance with the studies of V.M. Elterman given in the aforementioned above book on p. 34).

Thus, when implementing this technical solution, a technical result is achieved, which consists in automatic control of the temperature difference between the supply air and the room air, while intensive mixing is carried out inside the air distributor of the supply air and the air ejected from the room, and the range of the air jets coming from air distributor in the room.

Analysis of analogues showed that the claimed technical solution is new. The novelty of the solution lies in the fact that the design of the air diffuser provides tangentially at an angle to the plane of the lower end of the casing by supplying air into the casing from the air conditioning system, which leads to the twisting of this stream of jets and creates a vacuum in the upper inner zone of the casing, which, in turn, leads to the ejection of air from the room through the air intake gap made near the muffled end, and the tangential connection of the duct connected to the room to this gap provides m twisting and displacement of the ejected air with the air coming from the conditioning system. The location of the air intake slots ensures that both flows in the casing are twisted in one direction. The amount of air entering the air distributor for each duct is automatically regulated by dampers equipped with actuators connected to the regulators. Moreover, the mixing of air from the room from the air conditioning system is carried out quite smoothly thanks to the use of the friction pair “disk-damper”. The use of a diffuser at the output of the device reduces the range, i.e. quick damping of the speeds of the outgoing air jets.

Thus, the claimed technical solution is characterized by a new set of essential features that give a positive effect, and has signs of compliance with the criterion of "inventive step".

Figure 1 shows the proposed air distributor containing a cylindrical casing 1 with a diffuser 2 attached to the edges of the outlet 3 of the casing 1. The opposite end 4 of the casing is plugged. Near this end 4 in the casing 1 there is an air inlet slot 5, to which a cylindrical air duct 6 connected to the room and equipped with a flange 8 at the inlet 7 is connected tangentially to the surface of the casing 1. The damper 9, having the shape of a flat cylinder, is equipped along the edge of the cylinder base facing to the flange 8, the sealing gasket 10, and on the side surface of the shutter 9 is fixed a tape 11 made of friction material. The damper 9 is placed on the axis 12, on which the thread 13 is cut, the corresponding thread is cut in the central hole of the damper 9 to allow the latter to move in one direction or another until it fits snugly on the flange 8. The axis 12 is fixed at one end in a sleeve 14 located in the duct 6 and the rods attached to it 15. The damper 9 is tightly in contact with its side surface, on which the tape 11 is fixed, with the side surface of the disk 16, mounted on the shaft 17 of the actuator 18, i.e. a friction pair “disk-damper” is formed. The actuator 18 is electrically connected to a temperature controller 19, to which an air temperature sensor 20 is connected. On the diametrically opposite side of the casing 1 relative to the air inlet slot 5, another air inlet gap 21 is made, to which it tangentially to the surface of the casing 1 at an angle to the plane of the outlet 3 of the casing 1 a cylindrical duct 22 connected to the air conditioning system is connected. The duct 22 is equipped with a rotary valve 23, equipped with an actuator 24. The actuator 24 is electrically connected to an air flow regulator 25, to which a flow sensor 26 is connected. The actuators 18 and 24 are mounted on the brackets 27 and 28, respectively (the brackets are not included in the subject matter and in (the formula is not shown.) The location of the air inlet slots 5 and 21 ensures the flow of air coming from them in one direction in the casing 1 (in figure 1 - clockwise).

The air distributor operates as follows. The air coming from the air conditioning system through the duct 22 into the air inlet slot 21, due to the tangential connection of the duct 22 to the casing 1, is twisted inside the casing 1 at an angle to the plane of the outlet 3. The air flow through the duct 22 is regulated by a shutter 23 depending on the flow regulator 25 value. The controller 25 receives signals from the air flow sensor 28 and, when deviating from the set value, the controller 25 instructs the actuator 24 to turn the damper in one direction or another, opening or closing the section inside the duct 21 for air passage. Since the air inlet gap 21 is located below the blanked end 4 of the casing 1, and the air flow is directed downward (at an angle to the plane of the outlet 3), a vacuum will be created above the air inlet gap 21 inside the casing 1. As a result, through the air intake gap 5, to which the duct 6 connected to the room is connected tangentially to the surface of the casing 1, the air from the room is sucked (ejected), while the ejection process is smoothly due to the friction pair “disk-damper” providing smooth movement of the damper . This air flow swirls in the same direction as the flow from slit 21. Both air flows are mixed, while the air ejected from the room has a different temperature than the air from the air conditioning system. As a result, the latter changes its temperature and, thus, decreases the temperature difference between the air coming from the air distributor and the air in the room. The amount of air ejected from the room is regulated depending on the set temperature of the air entering the room, which is installed on the temperature controller 19, receiving signals from the temperature sensor 20. If the temperature deviates from the set value, the controller 19 will command the actuator 18 to rotate the shaft 17 in one or the other side. As a result of the rotation of the shaft 17, together with the disk 16 fixed thereon, tightly in contact with its side surface with a tape of friction material (a friction pair is formed), mounted on the side surface of the shutter 9, the latter also rotates along the thread 13 of the axis 12 in one direction or another up to to fit snugly to the flange 8, which is provided by the sealing gasket 10, while changing the gap between the shutter 9 and the flange 8 of the duct 6. Thus, the amount of air ejected through the duct 6 from the room changes, and this, in turn, it leads to a change in the temperature of the air flow (due to mixing with air from the air conditioning system) entering through the air distributor into the serviced room. In this case, the temperature difference between the supply air and the room air also changes. The presence of a diffuser 2 at the air outlet from the air distributor ensures a decrease in the dalbiness of the supply jets, i.e. a decrease in their speed and rapid dispersal in the room (in accordance with the studies of V.M. Elterman cited in the book of this author, mentioned earlier).

The proposed air distributor is industrially applicable, since it does not contain elements that are not manufactured by the industry and cannot be manufactured, and the assembly and installation of the device at the facilities does not present technical difficulties.

The proposed air distributor according to the principle of action, due to a new set of essential features, allows to reduce the temperature difference between the supply air and the room air, carrying out this process quite smoothly, to automatic mode. At the same time, the range of the supply jets is reduced.

Claims (1)

An air distributor containing a cylindrical casing with a diffuser mounted on the edges of the casing outlet in one of its ends, the opposite end of the casing is muffled, near the muffled end of the casing, an air inlet gap is made, characterized in that a cylindrical duct connected to the air inlet gap is connected to the casing the room, the inlet of the air duct is equipped with a flange, the air duct is equipped with a flap made in the form of a flat cylinder, in the center of the flap A threaded hole is made, the corresponding thread is cut on an axis along which the damper can move along the thread, the axis is fixed at one end in a sleeve mounted inside the duct coaxially with the latter and attached to the duct with rods, the plane of the shutter (cylinder base) facing the duct flange, equipped with a sealing gasket on the edge, and a friction material tape is fixed on the side surface of the shutter, while the end of the shutter tightly contacts this tape with the side surface of the disc fixed on the shaft of the actuator, forming thereby the friction pair "disk-flap", and the actuator is electrically connected to a temperature controller connected to the temperature sensor disposed at the outlet air from the diffuser; below the muffled end of the casing on the diametrically opposite side from the air intake slit, made near the muffled end of the casing, another air slit is made to which a cylindrical duct connected to the conditioning system is connected tangentially to the surface of the casing, connected to the air conditioning system, the duct is provided with a rotary damper, equipped with an actuator, to which the air flow regulator is electrically connected, and the date is connected to the regulator an air flow meter installed at the air outlet from the diffuser, while the location of both air intake slots in the casing ensures that the air flows coming from them in one direction inside the casing.