DE19521542A1 - Room ventilator with two air guide pieces, heat exchanger and heat pump - Google Patents

Abstract

The ventilator has a reversing switch (16) which is positioned between the air pipes (A-D) and the inflow or outflow pipes (1-4). In a heating position, the switch connects the air pipes to the inflow and outflow pipes. In the cooling position, the switch connects the first inflow pipe (1) to the fresh air pipe (B). The first outflow pipe (4) is connected to the air inflow pipe (C), the second inflow pipe (2) to the outflow pipe (A), and the second outflow pipe (3) to the air-escape pipe (D). The reversing switch unit has eight air ducts (a-d,a'-d') four of which in the two switch positions form the connections.

Description

The invention relates to a room ventilation unit with the Features of the preamble of claim 1.

Such a central ventilation device is in the Stiebel Eltron company logo, ventilation with Heat recovery, planning and installation, output March 1993, page 12 ff. This Room ventilation unit is suitable for room heating. A Room cooling, for example for hot summer months not provided.

In DE 94 13 690 U1 there is a central heating system for Building described. The underfloor heating provided there should also serve to cool the rooms.

The object of the invention is to provide a room ventilation unit to propose the type mentioned at the outset is further developed that it can also be used for room cooling is suitable.

According to the invention, the above object is characterized by the features of Claim 1 solved.  

The air flows can be controlled by means of the switchover unit in a simple way so that either a Heating or cooling is possible. Particularly advantageous is that the air ducts inside the Device does not have to be switched and still the Functions of the heat exchanger and the heat pump to be maintained. The changeover unit is one comparatively simple assembly, which is also can be subsequently installed on the room ventilation unit.

Advantageous refinements of the invention result from the subclaims and the following description. The drawing shows:

Fig. 1, a ventilation unit with changeover aggregate schematically, whose air passages in phantom for heating and for cooling dash-dotted lines are shown,

. 2a to 2c, an embodiment of a Umschaltaggregats in the "heating", Fig. 2a shows a cross-section, Fig. 2b and 2c are perspective views of FIGS,

FIGS. 3a to 3c, the changeover aggregate is in the "cooling", in which Fig 3a. A cross-section, Fig. 3b and 3c is a perspective view.

A room ventilation unit has a first inlet connection ( 1 ), a second inlet connection ( 2 ), a first outlet connection ( 4 ) and a second outlet connection ( 3 ). These sockets open at the top of the device housing ( 5 ). In Fig. 1, the discharge pipe ( 3 , 4 ) are shown pulled out of the device housing ( 5 ) for clarity.

A first air duct ( 6 ) runs in the device housing ( 5 ) between the first inlet connection ( 1 ) and the first outlet connection ( 4 ). This leads via an exhaust air fan ( 7 ), a cross-flow heat exchanger ( 8 ) and the evaporator ( 9 ) of a heat pump ( 10 ).

A second air duct ( 11 ) runs in the device housing ( 5 ), which leads the cross-flow heat exchanger ( 8 ) and the condenser ( 13 ) of the heat pump ( 10 ) via a supply air fan ( 12 ). The heat pump ( 10 ) works in the usual way with a compressor ( 14 ) and an expansion valve ( 15 ) between the evaporator ( 9 ) and the condenser ( 13 ).

The room ventilation unit is one for the air connection Exhaust duct (A), one fresh air duct (B), one Supply air line (C) and an exhaust air line (D) assigned. The exhaust air line (A) is on the to be heated or closed cooling building interior connected. Through the Exhaust duct (A) is air from the building interior sucked in. The fresh air line (B) is with the environment connected. Through the fresh air line (B) Ambient air sucked in. The supply air line (C) opens into the interior of the building. Through it this air becomes moves. The exhaust air duct (D) opens into the environment. It discharges air into the environment.

A switchover unit ( 16 ) is arranged between the air lines (A, B, C, D) and the line connecting piece ( 1 , 2 , 3 , 4 ). The switching unit ( 16 ) has air channels (a, b, c, d and a ', b', c ', d'). For heating, the air lines (A, B, C, D) are connected to the line sockets ( 1 , 2 , 3 , 4 ). The mode of operation during heating is approximately as follows (see Fig. 1, 2):

Via the exhaust air line (A), room air is extracted from the interior of the building by the exhaust air fan ( 7 ), which is led through the first air duct ( 6 ); At the same time, ambient air is drawn in by the supply air fan ( 12 ) via the fresh air line (B) and is led through the second air duct ( 11 ). In the cross-flow heat exchanger ( 8 ), the room air gives off heat to the ambient air. The ambient air on the condenser ( 13 ) is heated further and then supplied to the interior of the building as heated fresh air via the discharge nozzle ( 3 ), the air duct (c) and the supply air line (C). The extracted room air heats the evaporator ( 9 ) and is discharged into the environment via the discharge pipe ( 4 ), the air duct (d) and the exhaust air pipe (D).

For cooling, the air lines (A, B, C, D) are connected to the line sockets ( 2 , 1 , 4 , 3 ). The mode of operation during cooling is essentially as follows (see Fig. 1, 3):

Via the exhaust air line (A), room air is sucked out of the interior of the building by the supply air fan ( 12 ), which is led through the second air duct ( 11 ); At the same time, ambient air is drawn in by the exhaust air fan ( 7 ) via the fresh air line (B) and is led through the first air duct ( 6 ).

The suctioned ambient air is cooled on the evaporator ( 9 ) and supplied as cooled fresh air to the interior of the building via the discharge pipe (4), the air duct (d ') and the supply air line (C). The discharged room air heats up at the condenser ( 13 ) and is blown into the environment via the discharge pipe ( 3 ), the air duct (c ') and the exhaust air pipe (D).

For example, if the outside temperature in the summer months is 30 ° C and the temperature of the sucked-in room air is 28 ° C, then the sucked-in ambient air is slightly pre-cooled on the cross-flow heat exchanger ( 8 ). The evaporator (9) cools it down to around 24 ° C and blows it into the interior of the building at this temperature. The extracted room air is heated to around 38 ° C on the condenser ( 13 ) and blown off into the environment.

The room ventilation unit can therefore be used for both heating and cooling. The cycle of the heat pump ( 10 ) need not be changed. The heat pump works as a heating or cooling unit both for heating and cooling. The other components of the ventilation device known per se can also remain unchanged.

The switchover of the switchover unit ( 16 ) from heating to cooling can be made possible in the simplest case by the air ducts (a, b, c, d), which are designed as flexible hoses, being changed over individually or in groups, namely a from 1 to 2 , b from 2 to 1 , c from C to D and d from D to C. In principle, four hoses are sufficient for the changeover unit ( 16 ).

In carrying out the Umschaltaggregats (16) of Figs. 2 and 3 in a base body (17), a rotary member (18) is rotatably mounted about an axis (19). On the rotating member ( 18 ) handles ( 20 ) are formed for its actuation.

The exhaust air line (A), the fresh air line (B), the supply air line (C) and the exhaust air line (D) are connected to one side of the base body ( 17 ). The pipe sockets ( 1 to 4 ) are connected to the opposite side of the base body ( 17 ). The eight air channels (a, b, c, d, a ', b', c ', d') are formed on the rotating member ( 18 ). Rings ( 21 ) serve to stabilize the rotating member ( 18 ) and to rotate the rotating member ( 18 ) in the base body ( 17 ). The position in Fig. 2a, 2b and 2c is the heating position described above. The exhaust air line (A) is connected to the first supply pipe ( 1 ) via the air duct (a). The fresh air line (B) is connected via the air duct (b) to the second supply connection ( 2 ). The air duct (c) connects the supply air line (C) to the second discharge pipe ( 3 ). The air duct (d) connects the exhaust air duct (D) to the first discharge nozzle ( 4 ). The air channels (a ', b', c ', d') are ineffective in this position.

In Fig. 3a, 3b, 3c, the rotating member ( 18 ) is rotated by 90 ° with respect to the position shown in FIG . The exhaust pipe (A) is now connected to the second supply pipe ( 2 ) via the air duct (a '). The fresh air line (B) is connected via the air duct (b ') to the first feed pipe ( 1 ). The air duct (d ') connects the supply air line (C) with the first discharge pipe ( 4 ). The air duct (c ') connects the exhaust air duct (D) with the second discharge pipe ( 3 ). In this position the air ducts (a, b, c, d) have no effect.

The air channels (a to d ') can be formed by flexible hoses. It is also possible to design the rotating member ( 18 ) as a solid body and to design the air ducts therein. Instead of the rotary organ, a sliding member can also be provided, with which the connections mentioned can optionally be produced.

Via the exhaust air line (A) and the supply air line (C) several building interiors can also be connected to the device.

Claims (6)

1. Room ventilation unit with a first air duct, which leads from a first inlet connection ( 1 ) via a heat exchanger and the evaporation of a heat pump to a first outlet connection ( 4 ), and with a second air duct, which leads from a second inlet connection ( 2 ) via the Heat exchanger and the condenser of the heat pump leads to a second discharge pipe ( 3 ), with the first supply pipe ( 1 ) with an exhaust pipe (A), the first discharge pipe ( 4 ) with an exhaust pipe (D), the second supply pipe ( 2 ) for space heating. is connected to a fresh air line (B) and the second discharge pipe ( 3 ) to a supply air pipe (C), characterized in that between the air pipes (A to D) and the supply pipe or discharge pipe ( 1 to 4 ) there is a switchover unit ( 16 ) is arranged, in its one switching position (heating) the air lines (A to D) in the above-mentioned manner with the conductors connecting piece ( 1 to 4 ), and in its other switching position (cooling) the first supply pipe ( 1 ) with the fresh air pipe (B), the first discharge pipe ( 4 ) with the supply air pipe (C), the second supply pipe ( 2 ) connects the exhaust air duct (A) and the second discharge duct ( 3 ) to the exhaust air duct (D). 2. Ventilation unit according to claim 1, characterized in that the switching unit ( 16 ) has eight air channels (a, b, c, d, a ', b', c ', d'), four of which in each of the two switching positions Connect the mentioned pipe socket ( 1 to 4 ) with the mentioned pipes (A to D). 3. Room ventilation device according to claim 1 or 2, characterized in that the switching unit ( 16 ) has a rotating member ( 18 ) or slide member which has the air channels. 4. Room ventilation device according to one of the preceding Expectations, characterized, that the air channels are formed in a solid body. 5. Room ventilation device according to one of the preceding Expectations, characterized, that the air ducts of flexible pipe pieces are formed. 6. Room ventilation device according to one of the preceding claims, characterized in that the switching unit ( 16 ) is arranged on that side of the room ventilation device on which the supply connection piece ( 1 , 2 ) and the discharge connection piece ( 3 , 4 ) are located.