DE102008039010A1 - System wall, particularly for use as facade component as essentially ceiling-high prefabricated component, has interspace, which extends on largest part of height of system wall - Google Patents

Abstract

The system wall (1) has an interspace, which extends on the largest part of the height of the system wall and is covered with a vertical cover, particularly a glazing for external and internal sides. The interspace has an external air opening for through-flow of air to the atmosphere and an interior air opening for through-flow of air to the building interior.

Description

The The invention relates to a system wall, in particular as a facade element as a substantially space-prefabricated component.

It is known, glass facades of facade elements as prefabricated components reassemble. For the installation of heating, cooling, ventilation and shading creates a significant additional Effort.

task The invention is a system wall as substantially space high Prefabricated to create, with high flexibility and simple construction a maximum of energy efficiency offers and is preferably used in glass facades.

These Task is inventively characterized solved, that a gap is provided which extends over most of the height of the system wall extends and to the outside and inside each with a vertical cover in particular a glazing is covered, that the space for the passage of Air at least one outside air opening to the atmosphere and at least one inside air opening to the building interior and that in the space flowing through the air flow at least one heat storage in particular a latent heat storage and / or a heat exchanger is arranged.

A such system wall takes over with simple design and manufacture the functions of heating, cooling and ventilation, Room brightness control, privacy and significantly reduces this Energy requirement of a building. The system wall is as prefabricated as a building wall especially as a window can be used in a building exterior wall and has all components for efficient ventilation with optional cooling and Warming, Use of the outside and indoor temperatures, use of solar radiation, more efficient Shading and control engineering optimization of the interaction the individual components. This can be done more efficiently Control significantly saved on energy and an optimal climate in the rooms be achieved.

The for "fresh air supply serving" ventilation component "minimized the energy requirement through minimal internal flow velocities and Pressure losses. There will be integrated heat recovery between room and outside air achieved, in particular by an optional heat pump, the outwardly directed air Draws energy and this feeds the outside air supplied to the room again. Heat recovery and heat pump are umgeh- or switchable, so that also a "free cooling" by supplying cold outside air possible is. The energy requirement for the required air transport is minimized in particular by that temperature-related density differences of the air additionally used be, d. H. through the device reheated airflows pass the module from the bottom up, opposes cooling air streams from top to bottom. The cooling The air takes place in the upper unit area and the warming in lower device area, so that the upward or downward "chimney effect" caused by the density difference is maximum is.

requirement is the use of the maximum available Height within the system wall to achieve significant buoyancy forces. Preferably Axial fans for support the air flow used, which at standstill by folding wings the Pressure loss over minimize the fan.

The required electrical supply of the system wall is optionally via a also integrated photovoltaic module or via an electrical connection, which is the only interface to the building.

• – an der Außen- und Innenseite oder
• – im Scheibenzwischenraum befinden.

The disk module integrated in the system wall is a blind-disk system that can be used to influence the solar radiation into the room and also prevent it altogether, and also to prevent a radiation loss that is relevant, especially during the night. For this purpose, a combined with different blinds multiple glazing is used, which:

• - on the outside and inside or
• - located in the space between the panes.

Instead of a single or all blinds are electrochromic slices or coatings used where the properties in terms of Reflection and radiation transmission through an electrical voltage changeable are. To use the daily temperature course, d. H. in the Lower nighttime and higher daytime outdoor temperatures, has the system wall over a storage system that is powered by alternating with Outside- and room air can be charged and discharged. As storage material Preferably, phase change materials are used which are a maximum storage capacity have minimal storage volume. Depending on the season or the occurrence of a heating or cooling load when charging the "heat" or "cold" of the outside air stored and these supplied during the discharge of the room air.

In the case of heating, the charging process can alternatively or support by an additional to the Outside of the system wall located hot water collector done. In this case, the water heated by the solar radiation in the collector additionally or alternatively flows through the storage material located in the system wall and heats it up.

to Provision of the required to operate the individual components Auxiliary energy is the outside the system wall also equipped with solar cells, which solar irradiation convert into electrical energy.

advantageous Embodiments of the invention are listed in the subclaims.

Several embodiments of the invention are diagrammatic and vertical in the drawings Sections and are described in more detail below. Show it:

1 the schematic representation of a building with a system wall which is integrated as prefabricated part in the building,

2 a system wall with a shortened in height height representation;

3 the system wall after 2 at night in the summer, save the night cold;

4 the system wall after 2 by day in summer, the stored night cold discharge;

5 the system wall after 2 during the day in winter, save the daytime heat, convective and solar energy;

6 the system wall after 2 at night in winter, discharge the stored daytime heat;

7 the system wall in heating mode with minimization of the effort by buoyancy-related forces and lowest pressure losses for the air transport,

8th the system wall after 7 in cooling mode, while minimizing the expense of drive-related forces and lowest pressure losses;

9 a system wall with internal shading in the form of a blind,

10 the system wall after 9 with blind closed, to accommodate radiation losses and as privacy screens;

11 a system wall with electrochromic coatings on the panes of the glazing by day, for the targeted increase of the radiation loss;

12 the system wall after 11 at night, for a targeted increase in radiation loss;

13 the circuit diagram of an embodiment of a system wall according to the invention.

A system wall 1 forms the outer wall of a building 2 as a prefabricated component, in particular with a double-sided glazing. The system wall 1 thus forms a facade element, wherein the gap 3 extends over the greater part of the height of the facade element and to the outside and to the inside in each case with a vertical cover, in particular a vertical glass pane or a glazing 4 is covered. The system wall thus has at least the height of the building space and the interior or intermediate space 3 the system wall 1 is selectively and often alternately flows through in the vertical direction of the outside air or the room air, wherein in the intermediate space 3 Various devices / devices are arranged, in particular at least one heat storage as a latent heat storage 5 , at least one heat exchanger 6 . 7 , at least one fan 21 . 34 and / or a shading device such as a blind 8th or a roller blind. The combination of the components allows the adaptation of the system wall to different climatic zones.

In 2 is shown schematically that in the two-sided covers in particular the glazings 4 on the room side an upper inside air opening 9 and a lower inside air opening 10 and on the outside an upper outside air opening 11 and a lower outside air opening 12 are provided, these openings within the covers in particular of the glazings 4 or preferably at the outer edge of the cover, or glazing are arranged above and below.

In 2 is shown as warm room air over the opening 9 his energy to the heat storage 5 gives off and as cooled room air over the opening 12 reaches the outside. At the same time or later, cold outside air passes through the opening 11 to the heat storage 5 and is as preheated outside air over the opening 10 brought into the room of the building. How this can be used advantageously show the 3 to 6 , So is after 3 During the summer, cold outside air was passed through the heat storage tank at night and then brought outside again to cool down the storage tank, so that it could be used during the day 4 the room air can be cooled by the heat storage.

In the 5 and 6 you will be shown the reverse mode of action, in which warm outside air warms the heat storage tank in winter and accordingly 6 at night the cool room air from Heat storage is heated. Here, in addition, a solar collector 13 be used advantageously, the on a circuit 14 and a pump 15 connected to the heat storage to heat the heat storage in addition.

In 7 is shown as through the lower outside air opening 12 cold outside air through a down in the gap 3 heated heat exchanger arranged and preferably without a fan, or those with low power requirements due to low pressure through the gap flows up to the upper area through the upper inner air opening 9 to exit into the building room. Here, the upwardly flowing air in the space 3 be additionally heated by the sunlight. Such a construction has the considerable advantage that the expense of air transport is minimized, since the air flows automatically upwards and heats the room without requiring a fan.

In 8th the same construction is shown in the cooling mode, with warm outside air over the upper outside air opening 11 through an upper heat exchanger 7 through the gap 3 automatically flows down to over the lower inner air opening 10 get into the room, so that a room cooling is achieved without causing the air transport mechanically by a fan. Simply by regulating the shut-off devices in the air openings 9 . 10 . 11 . 12 The above mentioned functions of heating and cooling are achieved.

Here are the devices 6 . 7 either formed by a heat storage in particular a latent heat storage or by a heat exchanger which is connected to a latent heat storage.

In 9 is shown that between the two glass panes of the glazing 4 a blind 8th is arranged, which shadows the sun and with the blind closed, as in 10 shown, prevents radiation of heat or cold to the outside and also forms a privacy screen.

In the 9 and 10 The construction shown is preferably and particularly advantageous also used as a solar collector, which directly heats the space of the building. This occurs from below into the gap 3 Room air is absorbed by the sun's rays, in particular through the blinds 8th heats up and exits from the gap to the interior of the room. There is thus a direct heating of the building room. Alternatively or additionally, the in the space 3 heated air led to a heat storage, which in particular acts as night storage at night and depending on demand, the heat emits in the building room as heated air.

The 11 and 12 show outside electrochromic coatings 15 the glazing 4 through which the heat radiation is controllable without obstructing the view. Depending on the intensity of the solar radiation, the electrochromic coating ensures a greater or lesser radiation transmission.

In 13 schematically the flow diagram of an example of a system wall according to the invention is shown. Here, according to the 7 and 8th the fans 21 . 34 missing when the air currents within the gap 3 due to their heating upwards and due to their cooling down sufficient. In this embodiment, both a heat storage in particular a latent heat storage 29 as well as a heat pump with condenser / evaporator 22 . 35 as well as air filters 25 . 31 and a solar collector 38 arranged. By switching / mixing flaps 23 . 24 . 26 to 28 . 32 . 33 and 36 the different functions and applications of the system wall are controlled, for which purpose an electronic control is used, which measures with sensors the indoor and outdoor temperature, the indoor and outdoor humidity and / or after the day and / or season the components in particular the shut-off valves and fans 24 . 34 controls.

Especially It is advantageous if integrated control technology in the wall is provided, with the operator station directly (optional) in the Wall can be. this leads to to reduced interfaces and thus to lower costs.

The Integration carries the trend bill that the building services increasingly moving inwards and thus facades for renovation are easier to replace.

• – eines minimalen Installationsaufwandes,
• – einer maximalen Serienfertigung und
• – einer maximalen Energieeffizienz.

It is achieved the goal of arranging the technology and control technology and possibly the control technology in a wall, with the advantages

• - a minimal installation effort,
• - a maximum volume production and
• - a maximum energy efficiency.

Claims (18)

System wall ( 1 ) as a substantially room-high finished component, characterized in that - a space ( 3 ), which extends over most of the height of the system wall ( 1 ) and to the outside and inside each with a vertical cover in particular a glazing ( 4 ) is covered, - that the space ( 3 ) for the passage of air at least one outside air opening ( 11 . 12 ) to the atmosphere and at least one inside air opening ( 9 . 10 ) to the building interior, and - that in which the space ( 3 ) through at least one heat storage, in particular a latent heat storage ( 5 ) and / or a heat exchanger ( 8th . 7 ) is arranged. System wall according to claim 1, characterized in that at the top and at the bottom of the outside in each case at least one outside air opening ( 11 . 12 ) is arranged. System wall according to claim 1 or 2, characterized in that at the top and at the bottom of the inside at least one inner air opening ( 9 . 10 ) is arranged. System wall according to one of the preceding claims, characterized in that the latent heat storage ( 5 ) a heat exchanger ( 6 . 7 ) is connected, which is flowed through by the outside or inside air. System wall according to one of the preceding claims, characterized in that in the space ( 3 ) through at least one heat exchanger ( 6 . 7 ) is arranged, which is connected in particular via a heat pump with a heat exchanger, which is flowed through by the outside or inside air. System wall according to one of the preceding claims, characterized in that in the intermediate space ( 3 ) a solar radiation and / or the space heat radiation reducing device in particular a blind ( 8th ) or a roller blind is arranged. System wall according to one of the preceding claims, characterized characterized in that the inner sun blinds the solar energy in convective heat implement and over buoyancy forces an internal flow up support on the other hand, this energy is supplied to the heat storage can. System wall according to one of the preceding claims, characterized in that at least one glass pane ( 4 ) an electrochromic coating ( 15 ) having. System wall according to one of the preceding claims, characterized in that for supporting the vertical air flow at least one fan ( 21 . 34 ) is arranged. System wall according to one of the preceding claims, characterized in that the outside air opening (s) ( 11 . 12 ) and / or the inside air opening (s) ( 9 . 10 ) have a controllable obturator, in particular a flap or a valve. System wall according to one of the preceding claims, characterized in that the air flow in the intermediate space ( 3 ) is controllable such that it is either from a lower outside air opening ( 12 ) over the inner space ( 3 ) and in particular via a fresh heat the lower air heat exchanger ( 6 ) or latent heat storage up to an upper inner air opening ( 9 ) flows. System wall according to one of the preceding claims, characterized in that the air flow in the intermediate space ( 3 ) is controllable such that from an upper outside air opening ( 11 ) over the inner space and in particular an outer air cooling upper heat exchanger ( 7 ) or latent heat storage down to a lower inner air opening ( 10 ) flows. System wall according to claim 10 or 11, characterized in that the heat exchanger ( 6 . 7 ) with a latent heat storage ( 5 ) connected is. System wall according to one of the preceding claims, characterized in that at or in the vicinity of the outside at least one solar collector ( 13 ) is arranged, the received solar radiation energy via a line circuit ( 14 ) on a heat exchanger ( 6 . 7 ) and / or a latent heat storage ( 5 ) is deliverable. System wall according to one of the preceding claims, characterized characterized in that arranged on or in the vicinity of the outside at least one solar module is, by its electrical current, the electrical components operate. System wall according to one of the preceding claims, characterized characterized in that an electrical control is provided, by the indoor and outdoor temperature, after indoor and outside air humidity and / or according to the day and / or season the components in particular the shut-off elements and / or the / the fans are controllable. System wall according to one of the preceding claims, characterized characterized in that the required electronic logic as a control technique housed within the system wall. System wall according to one of the preceding claims, characterized characterized in that the operator station for air and air on the inside the system wall is attached.