RU2538516C1 - Plenum-and-exhaust plant with plate-like recuperative heat recovery unit - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: proposed plant includes a housing, a plate-like recuperative heat recovery unit, suction and exhaust fans, a filter element, a heating element of outlet plenum air, a heating element for exhaust air, a bypass valve, inlet and outlet holes for plenum air, inlet and outlet holes for exhaust air, and a condensate drain tray. The bypass valve is located between an outlet zone of exhaust air from the plant and an inlet zone of exhaust air to the plant. A control unit is made in the form of a microprocessor and connected to the suction fan with possibility of its being disconnected by switching in a defrosting mode of a plate-like recuperative heat recovery unit for circulation of exhaust air through the plate-like recuperative heat recovery unit via a closed circuit. Possibility of exhaust air flow via the closed circuit through the plate-like recuperative heat recovery unit allows using the heating element of outlet plenum air of lower capacity.

EFFECT: increasing energy saving of the plant due to reduction of energy consumption at operation of the plant in the defrosting mode of the recuperative heat recovery unit; simple design at absence of imbalance of plenum and exhaust air in a room at operation of the plant in the defrosting mode of the recuperative heat recovery unit.

3 cl, 2 dwg

Description

The invention is intended for use in ventilation and air conditioning devices at industrial, residential and public administrative facilities.

During the operation of recuperative heat exchangers in the winter, condensate falls out of the exhaust air, which leads to the formation of ice on the walls of the recuperative heat exchanger. Ice prevents the exhaust air from flowing through the recuperative heat exchanger, which makes its normal operation impossible.

A known ventilation apparatus comprising a housing with an inlet for supply air (supply-air intake port), an outlet for supply air (supply-air blowout port), an inlet for exhaust air (discharge-air intake port), an outlet for exhaust air (discharge-air blowout port), supply fan (supply-air blower), exhaust fan (discharge-air blower), heat exchanger (heat-exchanger), bypass valve (damper) and having an exhaust air inlet area, outlet zone exhaust air, supply air inlet area, supply air outlet area (cm Patent for invention EP 2581675, F24F 7/08, published on 04.17.2013)

The disadvantage of this analogue is that the bypass valve is located between the zone of exhaust air inlet to the unit and the zone of exhaust air from the heat exchanger, while the circulation of exhaust air from the zone of exhaust air from the plant to the zone of exhaust air inlet to the plant is impossible. The purpose of the bypass valve is to regulate the supply air temperature in operating mode. When freezing the heat exchanger, the movement of air through the heat exchanger is difficult, which creates an imbalance in the room. Thus, the problem of freezing the heat exchanger in this analogue is not solved, since the mode of thawing the heat exchanger in the operation of the analogue is not provided.

A known installation for organizing a microclimate in an agricultural building, including a housing, a plate recuperative heat exchanger, supply and exhaust fans, a supply air heater, a bypass valve, a supply air inlet into the installation, a supply air inlet from the installation, an exhaust air inlet into the installation, zone exhaust air exit from the installation, and the bypass valve is located between the exhaust air exit from the installation and the supply air exit from the exhaust air Ator (see. Russian patent №2219764, IPC A01K 1/00, publ. 27.12.2003).

In the defrosting mode of the heat exchanger, the bypass valve opens, and the exhaust air moves through the heat exchanger and leaves the installation through the supply air outlet, that is, it does not move through the heat exchanger in a closed circle.

The disadvantage of this analogue is that in the defrosting mode of the heat exchanger, the installation operates in recirculation mode, that is, the exhaust air is returned back to the room, which is unacceptable in a number of design decisions.

Closest to the claimed technical solution is an energy-saving ventilation and air conditioning system, including a housing with inlet and outlet channels for supply and exhaust air, connected to the control unit bypass valve, supply and exhaust fans, forming in the housing the corresponding input and output and exhaust air and exhaust zones air filter element inlet air, heating element inlet air, heating element for exhaust air, a bottom for draining condensate from a plate recuperative heat exchanger, and the bypass valve is made with the possibility of periodic opening and is located between the exit zone and the inlet zone of the supply air (see RF patent for invention No. 2244882, IPC F24F 5/00, F24F 11/00, publ. January 20, 2005 - a prototype).

The disadvantage of the prototype is that the bypass valve (bypass valve) is located in the supply air stream. In the case of freezing of the recuperative heat exchanger, the supply air moves bypassing the heat exchanger, which necessitates the use of a high power output air heating element.

The technical result of the invention is to increase the energy saving of the installation by reducing energy consumption during operation of the installation in the mode of defrosting the recuperative heat exchanger, in the simplicity of design in the absence of an imbalance of supply and exhaust air in the room during operation of the installation in the mode of defrosting the regenerative heat exchanger.

The technical result is achieved by the fact that in a supply and exhaust installation with a plate recuperative heat exchanger having inlet and outlet openings for supply air in the housing, inlet and outlet openings for exhaust air to the respective zones of exhaust air inlet to the installation and exhaust air outlet from the installation, filtering intake air inlet element, exhaust air inlet heating element, exhaust air heating element, plate condensate drain of the recuperative heat exchanger connected to the control unit bypass valve, supply and exhaust fans, the bypass valve is located between the exhaust air outlet from the unit and the exhaust air inlet into the installation with the exhaust air circulating through the regenerative heat exchanger in a closed circuit when the bypass valve is in defrosting mode of the regenerative heat exchanger, and the control unit is connected to the supply fan with the possibility of turning it off in Ad Mode.

Preferably, the control unit is connected to the supply fan via a switching means.

It is advisable to install a heating element for exhaust air in the housing.

The control unit is advisable to perform in the form of a microprocessor.

The essence of the invention is that the bypass valve is located in the exhaust air flow between the exhaust air outlet zone and the exhaust air inlet zone into the installation, which allows the exhaust air to circulate inside the installation in a closed loop, reducing the power of the heating supply air supply element in the absence of supply air imbalance and exhaust air in the room during operation of the installation.

When conducting patent research, no solutions were found that are identical to the declared one, and, therefore, the proposed solution meets the criterion of "novelty." The invention does not follow explicitly from the known solutions, therefore, the proposed invention meets the criterion of "inventive step".

Figure 1 shows the supply and exhaust unit with a plate recuperative heat exchanger, front view.

Figure 2 shows the supply and exhaust system with a plate recuperative heat exchanger, top view.

In figure 1, 2 the following notation:

1 - housing;

2 - plate recuperative heat exchanger;

3 - supply fan;

4 - exhaust fan;

5 - filter element (inlet air);

6 - heating element of the outgoing fresh air;

7 - heating element for exhaust air;

8 - bypass valve;

9 - inlet for supply air;

10 - outlet for the supply air;

11 - inlet for exhaust air;

12 - outlet for exhaust air;

13 - a condensate drain pan (from a plate recuperative heat exchanger);

14 - exhaust air exit zone from the installation;

15 - zone of the exhaust air inlet to the installation;

16 - zone of exhaust air exit from the plate recuperative heat exchanger;

17 - zone of the supply air outlet from the plate recuperative heat exchanger;

18 - control unit;

19 is a means of switching.

The boundaries of these zones 14, 15, 16, 17 in FIG. 1 are indicated by a dashed line.

The supply and exhaust unit with a plate recuperative heat exchanger contains (Fig. 1, Fig. 2) a housing 1, a plate recuperative heat exchanger 2, a supply and exhaust fan 3, 4, a filter element 5, a heating element 6 for the supply air, a heating element 7 for the exhaust air, bypass valve 8, inlet and outlet openings 9, 10 for supply air, inlet and outlet openings 11, 12 for exhaust air, drain pan 13 for condensate discharge. In the housing 1, a plate recuperative heat exchanger 2, a supply and exhaust fans 3, 4, and a bypass valve 8 are installed in such a way that the corresponding zones are formed: the exhaust air exit zone 14 from the installation, the exhaust air exit zone 15 into the installation, the exhaust air exit zone 16 plate recuperative heat exchanger, zone 17 of the supply air outlet from the plate recuperative heat exchanger. Bypass valve 8 is located between the exhaust air exit zone 14 from the installation and the exhaust air inlet zone 15 into the installation. In this case, the bypass valve 8 provides separation or connection of these zones 14, 15, respectively, in its closed or open positions corresponding to the control modes of the supply air temperature or thawing of the plate recuperative heat exchanger 2. The control unit 18 is made in the form of a microprocessor and is connected to the supply fan 3 its shutdown by means of switching 19 in the thawing mode of the plate recuperative heat exchanger 2 for circulating exhaust air through the plate recuperative heat exchanger 2 in a closed circuit. The switching means 19 can be made in the form of a relay or a key, which is part of the control unit 18 (Fig. 1). The control unit 18 can be made on the basis of the microprocessor controller "Pixel 2501".

Installation works as follows. In the control mode of the supply air temperature, the control unit 18 includes the supply and exhaust fans 3, 4, the bypass valve 8 is closed. In this mode, the supply air through the supply air inlet 9 enters the filter element 5, and then into the plate recuperative heat exchanger 2. The supply air moves the supply fan 3. After passing through the plate recuperative heat exchanger 2, the supply air is heated using the heating element 6 of the outlet supply air, after which it exits through the outlet 10 for the supply air. Exhaust air enters the inlet 11 for exhaust air, after which it enters the plate recuperative heat exchanger 2, and then exits through the outlet 12 for exhaust air. The exhaust air is driven by the exhaust fan 4. Bypass valve 8 is closed in this mode.

In the defrosting mode of the regenerative heat exchanger 2 by the control unit 18, the supply fan 3 is turned off, the bypass valve 8 is open. Exhaust air moves in a closed circuit through a plate recuperative heat exchanger 2, passing from the exhaust air exit zone 14 from the installation to the exhaust air inlet zone 15 into the installation through the bypass valve 8, being heated by the heating element 7 for exhaust air. The movement of the exhaust air is carried out by the exhaust fan 4. The possibility of movement of exhaust air in a closed circuit through a plate recuperative heat exchanger 2 allows the use of a heating element 6 of the outgoing supply air of lower power.

Compared with the prototype, the proposed installation allows to reduce energy consumption by 10-15%, the absence of problems with the imbalance of the supply and exhaust air in the room when the installation is in operation in the defrosting mode of the plate recuperative heat exchanger simplifies operation.

Claims (3)

1. A supply and exhaust unit with a plate recuperative heat exchanger, having inlet and outlet openings for the supply air in the housing, inlet and outlet openings for the exhaust air to the respective zones of the exhaust air inlet to the installation and the exhaust air outlet from the installation, a filter element of the supply air inlet, outlet air heating element, exhaust air heating element, condensate drain pan from a plate recuperative heat exchanger, connected to the control unit bypass valve, supply and exhaust fans, characterized in that the bypass valve is located between the exhaust air outlet from the installation and the exhaust air inlet into the installation with the possibility of circulating exhaust air through the plate recuperative heat exchanger in a closed circuit when the bypass valve is open in thawing mode of the plate recuperative heat exchanger, and the control unit is connected to the supply fan with the possibility of it turned off ia in the specified mode. 2. The supply and exhaust installation according to claim 1, characterized in that the control unit is connected to the supply fan through a switching means. 3. The supply and exhaust installation according to claim 1, characterized in that the control unit is a microprocessor.

Images