RU2459155C2 - Supply-exhaust device - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: device comprises a supply fan installed in an air channel, one end of which is connected to a ventilation nozzle, and the other one is divided into two channels, ejecting and supplying ones. The ejecting channel is connected with an inlet of an exhaust nozzle, an exhaust air duct is connected with the ejecting channel, via a heat exchanger, the inlet of a heat-release circuit in it is connected with an outlet of an exhaust air duct, and the outlet of a heat-release circuit is arranged in the form of an ejecting nozzle installed in the ejecting channel. The supplying channel is connected to an inlet of a heat exchanger heat-absorbing circuit, the outlet of which is connected with a vertical ventilation shaft. The outlet of supplying windows in premises is equipped with a heater.

EFFECT: using energy only to drive an axial fan, air motion is realised through simple and reliable devices and forces of natural circulation.

Description

The invention relates to ventilation and can be used in ventilation systems of buildings for various purposes.

Known supply and exhaust device with a regenerative heat exchanger, comprising a housing, channels for supply and exhaust air, a fan, a chamber with regenerative heat exchanger (see RF patent No. 2011127, IPC F24F 5/00, 1987).

A disadvantage of the known device is the relatively low efficiency due to the cross-organization of air flows.

It is also known a supply and exhaust device containing a fan installation, a vertical ventilation shaft, connected to the atmosphere by a receiving ventilation pipe, and with a room by supplying windows, an exhaust duct located in the shaft, connected to the rooms by exhaust pipes, and an upper end with an exhaust pipe providing discharge outgoing air into the atmosphere, in addition, the device is equipped with a heater for the air supplied to the premises (see RF patent No. 20044885, IPC F24F 7/06, 1993).

The main disadvantage of this scheme is the low heat transfer coefficient between the exhaust and supply air, due to the design of the heat transfer device having a relatively small heat transfer surface with significant cross-sectional areas. This leads to low speeds, which with relatively small areas of heat transfer creates a low efficiency of the heat exchanger.

The task to which the proposed technical solution is directed is to provide normalized parameters of indoor air with significant savings in electricity used to heat the outdoor air.

The technical result that is achieved when solving the problem is expressed in increasing the performance of air conditioning systems in the cold season due to energy savings, simplifying the design, installation and maintenance. When using the claimed solution, the temperature of the air supplied to the room does not differ much from the temperature of the air inside (no density difference), which is an additional advantage for small volumes of rooms (it is known that for ventilation, the temperature of the supplied air should be 2-3 ° C lower the temperature of the air in the room, and in a small-volume room with a constant stay of people - this is impossible, since the supply of chilled air to the lower part of the room can lead to lead to an uncomfortable state, while the application of the proposed solution when supplying air to the lower zone of the room does not adversely affect a person (does not cause unpleasant sensations due to its cooling).

The problem is solved in that the supply and exhaust device containing a fan unit, a vertical ventilation shaft, connected to the atmosphere by a receiving ventilation pipe, and with the room by supplying windows, an exhaust duct located in the shaft, connected to the rooms by exhaust pipes, and the upper end to the exhaust a nozzle that ensures the discharge of outgoing air into the atmosphere, in addition, the device is equipped with a heater for the air supplied to the premises, characterized in that the fan installation contains a supply fan located in the air duct, one end of which is connected to the ventilation pipe, and the other is divided into two channels - ejection and supply, while the ejection channel is connected to the inlet of the exhaust pipe, while the exhaust duct is connected to the ejection channel through a heat exchanger, the inlet the heat transfer circuit of which is connected to the outlet of the exhaust duct, and the output of the heat transfer circuit is made in the form of an ejection nozzle located in the ejection channel, in addition, the supply channel is connected to the course of the heat-receiving circuit of the heat exchanger, the output of which is connected with a vertical ventilation shaft. In addition, the outlet of the supply windows in the rooms is equipped with a heat heater.

A comparative analysis of the essential features of the proposed technical solution with the essential features of analogues and prototype indicates its compliance with the criterion of "novelty."

In this case, the distinguishing features of the claims solve the following functional tasks.

The sign "... the fan installation contains a supply fan ..." ensures the intake of fresh air from the outside of the ventilated room and its entry into the inside of this room.

Signs indicating that the supply fan is located “in the air channel, one end of which is connected to the ventilation pipe, and the other is divided into two channels - ejection and supply”, provide the possibility of dividing the supply air into two flows, one of which (larger in volume) goes to ventilate the room, and the other provides the formation of an ejection flow, stimulating the exhaust air from the room.

The sign "... the ejection channel is connected to the inlet of the exhaust pipe ..." ensures the discharge of exhaust air from the room into the atmosphere.

The signs "... the exhaust duct is connected to the ejection channel through an air heater, the input of the heat-transfer circuit of which is connected to the outlet of the exhaust duct ..." provide heat extraction from the exhaust air before it is discharged into the atmosphere, with the possibility of transferring this heat to the supply air.

Signs indicating that "the output of the heat transfer circuit is made in the form of an ejection nozzle located in the eject channel", provide the possibility of additional air intake from the heat transfer circuit of the heat exchanger and thereby additionally stimulate the process of removing air from the ventilated room.

The signs "... the supply channel is connected to the input of the heat-receiving circuit of the air heater, the output of which is connected to the vertical ventilation shaft ..." provide fresh partially heated air to the room.

The signs of the second claim provide the refinement of the supplied fresh air to normalized (comfortable) temperature parameters.

The drawing shows the supply and exhaust device and the organization of air exchange.

The drawing shows a fan unit 1, a vertical ventilation shaft 2, a intake ventilation pipe 3, supply windows 4, an exhaust duct 5, an air channel 6, an exhaust pipe 7, an exhaust pipe 8, an air heater 9, an ejecting and feeding channels 10 and 11, ejecting a nozzle 12, a flow separating partition 13 and a heat heater 14.

The supply and exhaust device contains a fan unit 1, a vertical ventilation shaft 2, connected to the atmosphere by a receiving ventilation pipe 3, and with a room by supplying windows 4, an exhaust duct 5, located in a vertical shaft 2, connected to the rooms by exhaust pipes 7, and the upper end with exhaust pipe 8, providing discharge of outgoing air into the atmosphere. The device is equipped with a heater 9 of the air supplied to the premises, for example, a plate recuperative heat exchanger. The fan unit 1 contains a supply fan, for example, of an axial type, located in the air channel 6, necessary for inducing air movement through the air channels and through the air heater 9, as well as for the operation of the ejection nozzle 12. One end of the air channel 6 is connected to the intake ventilation pipe 3, and the other is divided into two channels - the ejection 10, which ensures the operation of the ejection nozzle 12 with the help of the supply air pressure, and the supply 11, for supplying air directly to the room, flow-sharing eregorodkoy propellant 13. In this channel 10 is connected to the input of the exhaust pipe 8, and exhaust duct 5 connected with the entraining passage 10 through the efficient selection for the exhaust air heat air heater 9 by using it to heat the air supply. The input of the heat transfer circuit of the air heater 9 is connected to the output of the exhaust duct 5, and the output of the heat transfer circuit is made in the form of an ejection nozzle 12 located in the ejection channel 10 and used to stimulate the movement of the removed air, which is operated by the pressure of the flow of the supply air. In addition, the supply channel 11 is connected to the input of the heat transfer circuit of the air heater 9, the output of which is connected to a vertical ventilation shaft 2. Moreover, the output of the supply windows 4 in the rooms is equipped with a heat heater 14.

The device operates as follows.

Outside air, without preliminary preparation, enters the fan unit 1 through the intake ventilation pipe 3. After passing through the intake ventilation pipe 3, the air flow from the fan installation 1 is divided into two independent flows by a flow-separating partition 13 (to the ejection channel 10 and the supply channel 11). Next, the supply air is sent to a plate recuperative heat exchanger 9 (air heater), which through a vertical ventilation shaft 2 reaches a heat heater 14, which is a heating device in a decorative box. After processing in the heater 14, the air enters directly into the room (the supply stream, heating in the air heater 9, of course, does not reach the required (normalized) temperature value and, to achieve this, it is sent for heating to the heater 14). The exhaust air through the exhaust pipe 7 enters the exhaust duct 5. Then, having given heat to the supply air in the air heater 9, the exhaust air through the exhaust pipe 8 is removed by the volume of air that passes through the ejection channel 10, ensuring the “operation” of the ejection nozzle 12. The exhaust the duct 5 is coaxially mounted in a vertical ventilation shaft 2, which makes it possible to additionally heat the supply air entering it after the air heater 9 and thereby increase the efficiency of the installation. Thus, the supply air sequentially passes through three stages of heating: in the heat exchanger 9, in the exhaust duct 5 and in the heater 14.

Fresh air is supplied directly to the room from below, and exhaust air is removed from above. This solution provides energy use only for driving an axial fan. The movement of air is carried out using simple and reliable devices (air ejectors) and its natural circulation forces.

Claims (2)

1. A supply and exhaust device containing a fan unit, a vertical ventilation shaft, connected to the atmosphere by a receiving ventilation pipe, and with a room - supply windows, an exhaust duct located in the shaft, connected to the rooms by exhaust pipes, and the upper end - with an exhaust pipe, providing discharge of the outgoing air into the atmosphere, in addition, the device is equipped with a heater for the air supplied to the premises, characterized in that the fan installation comprises a supply fan, p displaced in the air channel, one end of the air channel of which is connected to the ventilation pipe, and the other is divided into two channels: the ejection channel and the supply channel, while the ejection channel is connected to the inlet of the exhaust pipe, while the exhaust duct is connected to the ejection channel through the air heater, the heat transfer input the circuit of which is connected with the outlet of the exhaust duct, and the output of the heat-releasing circuit is made in the form of an ejection nozzle located in the ejection channel, in addition, the supply channel is connected to the input of Plovareceiving circuit of the air heater, the output of which is connected with a vertical ventilation shaft. 2. The supply and exhaust device according to claim 1, characterized in that the output of the supply windows in the rooms is equipped with a heat heater.