RU119445U1 - EJECTION CLOSER - Google Patents

Abstract

An ejection closer containing a primary air chamber connected to the air duct located in the housing with nozzles mounted on it, a heat exchanger mounted on this chamber and connected to a heat or cold source, a mixing chamber with an inlet, and on the top cover of the housing there are holes for ejection from the surface glazing of internal air, characterized in that the air duct is located in the floor filling and is connected to the primary air chamber through a hole in the bottom of the case, and above the hole under the nozzles in the chamber there is a sound-absorbing plate attached to the side wall of the case, the length of which is equal to the length of the chamber, and the width is not more than half the width of the chamber.

Description

The utility model relates to the field of air conditioning and ventilation and is intended for use in residential, administrative and public buildings having a centralized or local supply of primary air, heat and water carrier.

Known ejector closure (see patent RU No. 103176, class F24F 1/01, publ. 03/27/2011), which is structurally made with the presence in the lower part of the chamber of the primary (sanitary norm of fresh air) air and nozzles are mounted on its upper part, and on either or on the same side of the nozzle arrangement along the length of the primary air chamber two or one heat exchanger are mounted, connected by a supply and return pipes with central sources of hot water supply in winter, and cold water supply in summer, while the front wall of the closer has an opening for I receive internal air to the heat exchanger, which is ejected from the room when the primary air exits the nozzles at a speed of no more than 16 m / s, and internal air ejected from the room, which passes from the fin side of the heat exchanger tubes, and if hot water passes through the tubes, Heats up in the winter, and when passing through pipes of cold water - it cools down. A mixing chamber is located behind the heat exchanger, where the primary and ejected air flows are mixed and the resulting mixture enters the room through the air inlet in the upper cover of the closer, and the duct for supplying fresh air to the lower chamber is connected to the pipe in the side wall of this chamber. In this device, the air mixture enters from the supply openings in the top cover under the ceiling, where harmful gases, water vapor, excess heat, i.e. those harmful substances that are emitted from people and decoration materials on the surface of building structures, furniture, equipment, the air entering the ceiling from the closer takes up some of these hazards, and having descended from the ceiling down into the people-inhabited area, the supply air from the closer returns part of the harmfulness to the breathing zone people, which significantly reduces the sanitary-hygienic qualities of the created microclimate.

The closest in technical essence to the proposed utility model is an ejector closer containing a primary air chamber connected to the duct with nozzles mounted on it, a heat exchanger mounted on this chamber and connected to a heat or cold source, a mixing chamber with a supply hole, holes for ejection from the glazing surface of the internal air are made on the top cover of the housing (see http://www.obitel.ru) The disadvantages of this closer design are I am:

- the flow of ejected air to the heat exchanger through an opening in the front wall leads to an increase in the mobility of air near the floor of a value more than acceptable for comfort = 0.3 m / s, which causes complaints about drafts from people who are sitting closer to the windows under which the door closers are mounted;

- the supply of fresh air through the nozzles of the primary air chamber leads to uneven distribution over the nozzles, there are significant difficulties in supplying and sheltering the supply air ducts to improve the appearance of the closer.

The objective of the utility model is to eliminate the noted drawbacks. The technical result consists in reducing up to 60% of heat consumption for the compensation of transmission heat loss through the lowest thermal resistance element of the building envelope;

The problem is solved, and the technical result is ensured by the fact that the ejection closer comprises a primary air chamber connected to the air duct with nozzles mounted on it, a heat exchanger mounted on this chamber and connected to a heat or cold source, a mixing chamber with a supply opening, and the upper housing cover has holes for ejection from the glazing surface of the internal air, and the duct is located in the floor and is connected to the primary air chamber through hole in the bottom of the hull, and over hole nozzles installed in the camera attached to the side wall of the sound-insulated housing plate whose length equals the length of the chamber and a width not more than half the chamber width.

The drawing shows a diagram of the proposed ejector closer.

The ejection closer includes a primary air chamber 1 with an opening 2 in its bottom. Around the perimeter of the hole 2, porous rubber 3 is fixed, the inner ends of which protrude by 2 ÷ 4 mm into the hole 2, into which, when mounting, the end 4 protruding from the floor is inserted from the supply air duct 5 of the outside air L.p. laid in the floor 6 and a noise-attenuating plate 7 is installed along the cross section of the chamber 1 at half its width 7. Nozzles 8 are installed in the holes of the upper wall of the chamber 1, a heat exchanger 9 is attached to its two posts 16, connected to a heat or cold source and assembled from finned bastard. On the upper part of the heat exchanger 9, a rotary nozzle 10 is connected, connected to the supply hole 11 in the front wall 12, in the upper cover 13 there are openings 14 for receiving internal air L e.e. that is ejected from the glazing surface, which extends from the fins of the heat exchanger tubes 9 mixed L.p. and L.E. and through the swivel nozzle 10, the mixture through the air inlet 11 at low speed = 0.3 m / s enters the service area of the premises inhabited by people.

The energy-saving ejector closer operates in the winter mode of heating the ejected air Lv.e. provided that hot water with a temperature of 50 ° C is supplied to the tubes of the heat exchanger 9. In the central supply unit (not shown in the drawing) L. heated in winter to a temperature of t.p.x. = 6 ° C and through the supply air duct 5, with the end 4 protruding from the floor filling 6, secured and sealed in the bottom of the chamber 1, the ends of the porous rubber 3 protruding into the opening 2 and through the end supply air duct 5 sanitary norm L.p. enters the primary air chamber 1 and, enveloping the surface of the noise-attenuating plate 7 located above the hole 2 under the nozzles 8, with uniform distribution it enters the nozzles 8 and through the openings in them at a speed of no more than 16 m / s, which avoids noise coming out of the nozzles jets of air, enters the chamber 15, where the kinetic energy of 8 jets Lp.n. creates the effect of ejection of internal air L.E. from the glazing surface and the entry of L.e. through the hole 14 in the top cover 13 to the finned tubes of the heat exchanger 9, through which hot water flows from the pump (not shown in the drawing), and its flow rate is controlled by an automatic valve in the supply pipe by the signal from the control sensor tv.x. = 20 ° C ( not shown), and heated L.E. and cold L.p.x. with t.p.x. = 6 ° C are mixed in the chamber 15 and the resulting mixture through the rotary pipe 10 enters the supply hole 11 in the front wall 12 and, going out into the room, fills the people’s living area and displaces the gas polluted to the ceiling to the exhaust hole, moist warm air, which is removed from the operation of the central exhaust unit (not shown in the drawing). Removing all the harmful effects ensures high sanitary and hygienic qualities of the air in the area where people live, and when the outside temperature rises in winter and the solar radiation appears to glaze in the living room, the inflow of heat from the penetrating solar radiation through the glazing and mixing of the transmission heat loss increases with increasing t. higher than the calculated winter temperature tn.x. (for Moscow tn.x. = - 28 ° C) in the habitat of people there will be an excess of heat inflows, which will cause an increase in tv.> tn.x. = 20 ° C and a control sensor at t..x. = 20 ° C gives a signal to reduce or even completely stop the supply of hot water to the tubes of the heat exchanger 9 and the ejected air Lv.e will be mixed in the chamber 15 and cold L.p. with t.p.x. = 6 ° C, which will allow to absorb heat surpluses in the habitable zone, maintain a comfortable winter air temperature tv.x. = 20 ° C and prevent excessive heat from hot water in the heat exchanger 9 during overheating of the inhabited zone tv.> tv.x. = 20 ° C; during the transition period of the year neither hot nor cold water is supplied to the tubes of the heat exchanger 9, and t.p. is supplied from the central supply unit to the nozzles 8. from 6 ° to 17 ° C depending on the growth of t .; at tn> 17 ° C, the warm season begins, at which a comfortable summer temperature tv. = 23 ° ÷ 25 ° C is maintained in the habitable zone of the room, and if tv. If it is higher than 25 ° C, then from the operation of the pump cold water will be supplied from the tube of the heat exchanger 9 with a temperature equal to or higher than tw.x. = 14 ° C, which will allow cooling the ejected air L.e. in heat exchanger 9. no moisture condensation.

Claims (1)

An ejector closer containing a primary air chamber connected to the air duct with nozzles mounted on it, a heat exchanger mounted on this chamber and connected to a heat or cold source, a mixing chamber with a supply hole, and holes for ejection from the surface are made on the top cover of the housing glazing of internal air, characterized in that the duct is located in the floor and is connected to the primary air chamber through an opening in the bottom of the housing, and above the opening TIFA under the nozzle installed in the chamber attached to the sidewall of the sound-insulated housing plate whose length equals the length of the chamber and a width not more than half the chamber width.