DE4100674A1 - Combined heating and ventilating system - comprises circuits boosted by heat exchangers and pump and controlled by valves - Google Patents

Abstract

A heating and ventilating system for a number of rooms connected by a heating circuit consists of several elements which produce and give off heat. A boiler (1) is connected to a hot water storage cylinder (2) which in turn is coupled to a heat exchanger (3) incorporated in a ventilator (4) with a fresh air intake (4'), and a pump (5). Another heat exchanger (6) integral with the cylinder (2) is connected to the heat exchanger (3) in the ventilator (4), and a further heat exchanger (7) associated with the pump (5). The air supply duct (5') from the pump (5) has several suction openings in different rooms (8), and the air distribution duct (9) from the ventilator (4) has a number of discharge points in different rooms (10). The return pipe (11) from the heat exchanger (3) is connected to the heat exchanger (6), a three way valve (12) between the flow (14) and return (15) of the boiler (1), and the flow pipe (11') from the heat exchanger (3) is connected to the boiler flow (14) and a two way valve (12). USE/ADVANTAGE - An econimic and comprehensive combined heating and ventilating system.

Description

The invention relates to a heating and ventilation system for several rooms covered by the heating circuit.

The development in heating technology has been largely determined in recent years by further reducing the pollutant emissions that occur during combustion. Previously, NO _x and CO emissions were the focus, now and in the future the measures to reduce emissions will play a role CO ₂ emissions play an important role.

The amount of CO ₂ emissions resulting from the combustion of fossil fuels is directly related to energy consumption. In contrast to NO _x and CO emissions, it can only be reduced by reducing energy consumption.

The large savings and thus CO ₂ reduction opportunities in the field of building heating offer a further improvement in the energy use of heating systems and a reduction in heating requirements.

Assuming that a Hei power plant with a high annual utilization rate and thus optimal energy efficiency is operated, the Reduce energy consumption further when heating needs of the building is reduced.  

If an average heat requirement of approx. 80 to 100 W / m ^{2 of} living space is achieved according to the currently applicable Heat Protection Ordinance of 1982, then requirements must be expected in the future that provide for a heat requirement of approx. 40 to 50 W / m ² . In order to meet this requirement, in addition to appropriate thermal insulation of the building, high demands must also be made on the design of the room ventilation in order to reduce ventilation heat losses. The fact that a low heat requirement of 40 to 50 W / m ^{2 can} also be achieved in practice is shown by the buildings constructed under the designation "low-energy house", which are generally equipped with domestic ventilation.

By living in buildings, it is contained in them room air is contaminated with various substances and such with the indoor air quality affected. Essentially is it carbon dioxide, odorants, Tobacco smoke and water vapor. A high water vapor Content in the room air not only affects the load comfort, but can also lead to structural damage. Due to a "dense" design of living clearing or building is for health and be comfort, but also to avoid structural damage important natural air changes will no longer be possible in the future give. The ventilation previously practiced for this by public However, the window proves to be in several ways out of date: With this type of ventilation  not only wasted considerable heating energy and thus acted contrary to the required energy saving, but in densely populated areas or on traffic streets reach through the open windows next to ver dirty air also noise in the rooms.

Both lower energy consumption as well This leads to high air quality requirements ren that the technical building equipment by a special our home ventilation must be expanded.

The practical knowledge that has been available for years and the latest scientific research shows that in living rooms a 0.5 times air change in the Re gel is sufficient. For this task different systems have already been developed. Crucial for the use of home ventilation is that for that required equipment technology both from the heating specialist and is also endorsed by the plant operator. Only then combined home ventilation and heating enforce at all, with the following demands Must be taken into account:

• - low energy consumption and adapted fresh air supply,
• - exhaust air heat utilization or heat recovery,
• - manageable, easy to carry out planning,  
• - compact, easy to install devices,
• - low installation effort,
• - easy maintenance / service,
• - high comfort (low noise level; draft-free, clean Air).

Proceeding from this, the object of the invention is to create a combined heating and ventilation system, with these demands in the simplest possible way can be satisfied, with the proviso that existing To be able to retrofit heating systems just as easily.

This task is with a heating and ventilation system of the type mentioned according to the invention by the in Characteristics of the main features listed ge solves. Advantageous further developments result from the Subclaims.

This system according to the invention thus has three main compos nenten, namely heat generation (boiler), ventilation device with supply air distribution and exhaust air routing with heat recovery (heat pump). It is essential how these elements (boiler, water heater, heat pump and ventilation unit) within the system who are linked.  

The system according to the invention thus retains the conventional one Hot water heating, but combines them in combination with a ventilation and heat recovery system, being what still follows from the description in detail reveals that all conditions are in place for the Heating specialist with the introduction of housing ventilation related tasks can easily be realized times this the individual components required for this knows essentially from his previous work. The boiler is in the system as before bound - both hydraulically and on the exhaust side -, which, as will be explained later, enables that complete home ventilation for existing boiler systems retrofit.

With the arrangement of most device components in the open space of the boiler and the draft device with its small footprint in a place that in the mei In most cases, only short supply air lines are required Requirements for a low installation effort ben.

The heating and ventilation system according to the invention below based on the graphic and schematic Representation of an execution and arrangement example explained in more detail.  

Oriented to this illustrated system example, he follows the heating of the building or apartment by the boiler 1 (heating circuit I), which is installed in the basement and is connected to the heating circuit (II) in a known manner. The ventilation device 4, which is largely known in the living area, is designed for an air output of, for example, 200 m ³ / h. This means that average apartments can be supplied with sufficient fresh air. This relatively small size (approx. 640 x 340 x 200 mm ³ ) has ventilation unit 4 is equipped with an air filter, a heat exchanger 3 and a blower 17 and can advantageously also be equipped with an electric heating element 16 , which only has to have a relatively low heating output, as shown.

The filtered outside air is heated to room temperature by the WT3 connected to heating circuit II. The connection to the heating circuit II (in the area of the memory 2 ) creates in conjunction with a thermostatic valve installed in the flow of the ventilation device the prerequisite for keeping the supply air temperature at the desired value. The supply air is supplied through the air discharge line 9 with its Lufblasblasöff openings 10 to the living room and bedrooms. A central arrangement of the ventilation unit, e.g. in the hallway or in the hallway, results in short supply air lines to the rooms - this means that the installation effort is kept to a minimum. The warm exhaust air, for example from the kitchen, bathroom and toilet is fed through an air supply line 5 'to the hot water heat pump 5 installed in the basement, which takes over the function of heat recovery. The resulting slight negative pressure in these rooms ensures that kitchen smells and bathroom moisture do not get into the living room or bedroom. Possibly. warm air can also be supplied from the boiler installation room to the heat pump 5 .

For example, a warm water heat pump 5 is used , which is attached to the DHW cylinder 2 . The electrical power consumption is, for example, 590 W at a hot water temperature of 55 ° C. The average heating capacity for hot water heating of 15 ° C is 1.39 kW.

The heat exchanger 7 (Ver liquefier) of the heat pump 5 arranged in the storage 2 below transmits the heat extracted from the exhaust air to the process water in the storage 2 . The amount of heat supplied to the accumulator 2 by the heat pump 5 primarily covers the energy requirement required for heating the process water. With an exhaust air volume flow of approx. 200 m ³ / h, approx. 800 W can be recovered from the exhaust air. The heat recovery from the exhaust air therefore delivers a maximum of approx. 19 kWh of heat per day. In the case of a four-person household, an average of 10 kWh can be assumed for the daily amount of heat required for domestic water heating, including circulation and storage losses. With the difference of 9 kWh plus the heat output of the compressor of the heat pump 5 of 14 kWh, the ventilation device 4 is supplied for heating the outside air. The heat exchanger 6 present in the store 2 serves to remove the heat required for this from the store 2 . The amount of heat is sufficient to provide 200 m ³ / h of outside air. B. heat from 11 to 25 ° C. At lower outside temperatures, the boiler 1 heats up. There is also the option of supplying the bathroom with heat in this way in the summer or during the transition period via a separate wet strand.

The heat exchanger 6 in the store 2 also makes it possible to heat the store 2 from the boiler 1 , which may be necessary due to a short-term high demand for hot water. The integration of the heat pump 5 in the system, as described and shown, both for hot water preparation and for the heat supply for the ventilation unit creates ideal conditions for using the waste heat from the home ventilation. The exhaust air temperature in the range of 20 to 22 ° C, which is constant almost all year round, has a decisive influence on this.

The heat pump 5 herewith available tem perature is thus higher than this when supplying air from installation rooms, for. B. the basement, the case is. The high suction temperature and year-round operation of the heat pump 5 enable its particularly economical function.

An essential feature of the system is that it is uncomplicated graceful hydraulic integration of the ventilation into the heater tongue. This is also a very good basis for the Integration of this system in existing systems given.

As mentioned, the WT3 of the ventilation unit is also connected to the heat distribution downstream of the boiler. The heat required for the WT is taken in the summer and in the transitional period via the heat exchanger 6 arranged in the store 2 from the stored domestic water. During this time the boiler 1 is out of operation.

As the heating season begins, the heat required to heat the cold outside air also increases. The performance of the heat pump 5 is no longer sufficient at outside temperatures in the range from +8 to + 12 ° C, in addition to heating the domestic water to supply the ventilation unit 4 with sufficient heat. The boiler 1 is then automatically switched on via the three-way switch valve 12 . The return water of the ventilation unit circuit LK is first passed through the heat exchanger 6 in the memory 2 and preheated. The heating to the required temperature is then carried out by the boiler 1 , which is in operation during the heating period anyway.

In addition to the uncomplicated hydraulic integration, this system is also useful thanks to a low level of regulation technical effort. The three main components of this Systems - heat generation by the boiler, ventilation unit and exhaust air duct with heat recovery - set each represent and can have closed control loops can be linked together with little effort. One There is no need for a more detailed explanation in this regard known elements and circuit principles without white teres are available and known.

As can be seen from the description and representation, the entire system consists practically of five circles, namely the heating and heating circuit I, II, the ventilation unit circuit LK, the storage circuit SK and the heat pump circuit WK, the storage circuit SK, ie its heat exchanger 6 , also forms part of the fan unit circuit LK at the same time.

As mentioned above, an electric heating element 16 can be provided in the fan unit, which does not provide the same heat output as the heat exchanger 3 , which heats and heats the supply air when operated with heating water. The electrical heating resistance can switch on via a thermostat if, for. B. the outside temperature has dropped, but not so much that the room heating must be switched on. Then, in this transition phase, the electrical heating resistor could additionally heat the room air to the required temperature. Here, too, the control is simple, since only one thermostat is to be provided, the heat sensor of which is arranged behind the heat exchanger 3 which switches the heating resistor on and off as required.

With a possibly the ventilation unit 4 associated time (not shown) timer can be ensured that the fan 17 on and off periodically switched. The drive for the blower 17 is expediently designed to be switchable in two stages in order to be able to promote fresh air in accordance with requirements.

Claims (5)

1.Heating and ventilation system for several rooms covered by the heating circuit consisting of several interlinked heat-generating and heat-emitting elements, characterized by the combination of the partially known features:

• 1.1 with the heating circuit (II) connected to the heating circuit (I) of the boiler ( 1 ) is connected to a water heater ( 2 ) or storage;
• 1.2 the hot water tank ( 2 ) is connected to a heat exchanger ( 3 ) in a fresh air intake connection ( 4 ') provided with a ventilation device ( 4 ) and with a heat pump ( 5 );
• 1.3 in the domestic hot water tank ( 2 ) is connected to the heat exchanger ( 3 ) of the ventilation device ( 4 ) connected heat exchanger ( 6 ) and the heat emitting heat exchanger ( 7 ) of the heat pump ( 5 );
• 1.4 the air supply line ( 5 ') of the heat pump ( 5 ) has several suction openings ( 8 ) distributed in different rooms;
• 1.5 the air discharge line ( 9 ) of the ventilation device ( 4 ) has a plurality of air outlet openings ( 10 ) distributed over different rooms;
• 1.6 the return line ( 11 ) of the heat exchanger ( 3 ) in the ventilation device ( 4 ) is via the heat exchanger ( 6 ) of the domestic hot water tank ( 2 ) and a three-way valve ( 12 ) in a connection ( 13 ) between the flow and return ( 14 , 15 ) of the boiler ( 1 ) out;
• 1.7 the flow line ( 11 ') of the heat exchanger ( 3 ) is connected to both the flow ( 14 ) of the boiler ( 1 ) and the two-way valve ( 12 ).

2. Installation according to claim 1, characterized in that an electrical heating element ( 16 ) is arranged in the ventilation device ( 4 ). 3. Plant according to claim 1 or 2, characterized in that the ventilation device ( 4 ) is provided with a timer for periodic switching on and off of a fan ( 17 ) arranged in the ventilation device ( 4 ). 4. Installation according to one of claims 1 to 3, characterized in that at the end of the exhaust line ( 5 ') on the suction side a fan ( 18 ) is arranged and this pressure side is directed to the heat exchanger of the heat pump ( 5 ). 5. Plant according to claim 3, characterized in that the fan ( 17 ) is provided with a two-stage switchable drive.