DE2327614C3 - Device for air conditioning or temperature control of rooms - Google Patents

Description

The invention relates to a device / to air conditioning or temperature control of rooms by the Usage, we have a higher, pure need for fresh air, with the air being pretreated in an upstream switchgear and is conveyed with increased pressure via an air duct system to the rooms to be ventilated, with an expansion device connected downstream of the ballast, which is followed by a heat exchanger, and with a reversible locking device, which enables the pre-treated air to be blown into the room via the heat exchanger or convection mode is also permitted after switching.

De. The expression "pretreat" is used in the Air conditioning is used in the usual way, and it means air filtering, heating or cooling. Heat recovery or air humidification or -i-ocknung etc. of the supply air for rooms so that their Users receive optimally contracted and hygienically perfect air.

Air conditioning systems and ventilation systems often need window ventilation, which is made up of a wide variety of Reasons may not be possible to replace. In such systems, the per person and hour required amount of fresh or outside air via a ventilation center and air ducts to the individual Floors and utility rooms, and from there via appropriately designed air outlets so in the usable spaces are blown out so that no impairment or even health problems for the users of the rooms as a result of drafts or too cold or air that is too warm. It goes without saying that the corresponding amounts of exhaust air through a special facility can be removed from the rooms.

According to the current state of the art, induction devices or air conditioning convectors are becoming more well known Design preferably used for air conditioning in larger office and administration buildings. she are mostly built into the window sill. With the air conditioning processes used here it depends on the indoor air conditions (temperature and humidity) in the sometimes very different used rooms according to the occupancy within the comfort limits and / or to keep it largely constant according to the time of day, the season or other necessities.

It has long been known to use so-called low-pressure air conditioning systems, however When installing in larger buildings, require air ducts with considerably large cross-sections, which makes them more valuable Usage space is lost. To limit the dimensions of air conditioners, one is particular moved to high-pressure air conditioning systems in larger buildings, in which air conditioning convectors are used working on the induction principle.

The air duct ·: for these systems, as a result of the increased air pressure !, and the increased air (speed Significantly smaller dimensions than in known low-pressure air conditioning systems. Except The pressure induction air conditioning systems can do this with much smaller amounts of air from the actual Air conditioning / entrale (which are often in the basement or on the roof of the building) / u the grooves operated, as only the minimum ventilation required per person and hour is required Grouting spaces are supplied to muli

In the case of high-pressure induction air conditioning systems, the fresh air that is under increased pressure is in the induction unit. or air-conditioning convector relaxes via nozzles, and it tears the room air at the relaxation point in accordance with the induction effect. In the device air · wes for the room air there are one or more heat exchangers through which the room air can be post-treated, ie post-heated or post-cooled (DTAS Ib 04 277. DT-AS 11 67 507). The heat exchanger in the device air path ensures that, when mixed with the high-tension supply air that is pretreated in the ballast, the dor! With other things being either pre-cooled or pre-heated, the correct temperature is created for the air given off by the air-conditioning convector. On the other hand, high-pressure air conditioning systems are also known in which the pretreated, pressurized air supplied to the convector entrains the unprocessed room air or secondary air when it relaxes and mixes with it, and in which this air mixture is then post-treated and in the relaxed state is conducted via the radiator or heat exchanger designed as an air-conditioning convector into the usable space. Such a system is known from DT-AS 11 47 367, for example.

Some devices or air conditioning convectors for such air conditioning systems can already perform a double function insofar as they allow, in addition to air conditioning or ventilation operation, when the air conditioning center is not running (e.g. at night), a certain, mostly low level of natural convection for static heating of the usable spaces via the heat exchanger ( see DT-AS 11 67 507. Column 2, lines 28 to 35).

In these high-pressure induction air-conditioning systems, however, when there was a higher demand for fresh air or -throughput in addition to the inadmissible noise pollution, especially because of the induction effect Completely intolerable drafts arise in the occupied zone, especially in connection with the always as Secondary air roller to the device returning secondary air flow an excessive amount of air constantly in the Space would be circulated.

The problem of drafts becomes particularly severe when the aforementioned High pressure induction air conditioners. used in rooms should be, in which as a result of high occupancy (e.g. meeting rooms) or more intensive Use (e.g. laboratories) there is a high or 100% pure fresh air requirement, or by correspondingly mandatory regulations, e.g. B. is essential in terms of health technology.

Therefore the previously known fan coil units, which operate on the principle of induction of the type indicated, are only suitable for use in the office or similar use in spaces with normal Perso ⁶ S nenbesetzung. In practice it has been shown that the air conditioning of office rooms that are occupied with at least about 6 m ^{2 of} space per person is entirely possible with the Khmakonvectors according to the induction principle. However, if z. B. School. Suz- or lecture rooms, in which only about 2 m 'and less per person are available, or in which laboratory or hospital rooms are to be supplied with the required high level of fresh air, then these rooms can no longer be controlled using an air-conditioning method based on the induction principle or ventilate with the help of air conditioning convectors that work according to this principle, as the high circulation of air in the room would lead to drafts and thus inevitably to the dreaded, creeping damage to health.

Apart from the difficulties mentioned above, certain areas of application, such as e.g. For example, hospital, school and laboratory operations take special measures as the addition of room air to fresh air (according to the induction principle) is not permitted for hygienic reasons. as there is an increased risk of infection as a result of the contamination effect (implantation or distribution of infectious agents and viruses via primary channels to other rooms). The formation of infection nests in the heat transfer part of induction air conditioning units can also cause serious health problems. The reuse of room air as secondary air is forbidden for laboratory operations, since there is a risk that acid fumes or other corrosive substances, for example, are spread during operation of the laboratory and that the internal parts of the device were exposed to increased corrosion or premature destruction.

In summary, it can be stated that the high-pressure air conditioning convectors on the market b / w. Induction devices, especially when used as built-in devices for window sillings, are very well suited for air conditioning or ventilation of office rooms with normal occupancy (at least about 6 m ² per person), especially since they still have one when the air conditioning center is down (e.g. at night) allow certain static room heating by self-convection, corresponding to the only small radiator or heat exchanger surface. However, these devices are not applicable for meeting, lecture and school rooms (with about 2 m- 'and less per person) and furthermore for laboratories and hospital rooms, because the increased fresh air requirement would result in an inadmissibly high room air circulation, which is especially important here would lead to unbearable drafts; ie the entire induction process cannot be used for these purposes.

The unsuitable induction devices have therefore been abandoned for the applications mentioned and switched to devices of the type mentioned, which optionally operate with pure Enable fresh air supply or pure convection operation. Such devices are for example already described in DT-OS 19 31 155.

The devices known from DT-OS 19 31 155, which are preferably used for laboratories and industrial rooms are to be, however, are relatively complicated in that they are generally a multi-part Have locking device, the parts of which must all be actuated to selectively one or the other to enable other operation. Each part has its own function. The parts of the locking device are 'partly jointly and partly

operated separately via actuating devices. These devices are therefore relatively complicated in their structure and therefore prone to failure.

. The device shown in Fig. 7 of the DT-OS 19 31 155 has, for example, as a locking device on several flaps, which with the help of rods and actuating motors adjusted. There are already two operating states, namely for blowing in the pretreated air via the heat exchanger as well as for convection operation via the heat exchanger, possible by appropriate positions of the flaps, but this device is complicated and thus prone to failure. Furthermore, in this known feerät intermediate positions of the flaps for the purpose of temperature control intended. It can therefore in a system that has such devices, after switching off the Ballast Air from one room to another room via the air duct system, i.e. it Inadmissible contamination effects can thus occur.

In addition, the exact adjustment of the different Verstellmotorhübe and the operating linkage is quite complex and difficult. especially when two flaps are controlled with one motor, and when all flaps are also regulation-dependent Can take intermediate positions, even in convection mode. Absolutely let yourself coordinate several large-format flap feeds so precisely with each other only with great effort and care, that ζ. B. in fresh air operation no undesired room air enters through the flap. So are these devices in the version with several regulating flaps can only be used to a limited extent.

In Fig. 4 of the DT-OS 19 31 155 is indeed as a locking device only one flap provided. However, this flap only serves to close the room air opening during ventilation operation and therefore only has one function. The fresh air opening cannot be shut off as the blower runs inside the device. A system that uses such devices can operate with convection or after switching off the preconditioning system for air via the duct system from one Get into the other space, d. This means that impermissible contamination effects can also arise.

The invention is based on the object of providing a simple device of the type mentioned at the beginning for temperature control or to create air conditioning of rooms, through which the required when using the room in the ballast treated fresh or outside air 100% post-treated as fresh or outside air and is supplied to the room and through which the fresh or outside air supply when the room is not in use completely ended and then pure convection operation carried out with the help of the heat exchanger to prevent the room from cooling down (ζ. Β. at night).

This object is achieved in the device according to the invention in that the locking device either to completely shut off the pretreated air and to release it completely at the same time the convection air path or to completely shut off the convection air path and at the same time completely releasing the path for the pretreated air is alternately switched.

When using such trained according to the invention devices for air conditioning or ventilation and The temperature control of the rooms used is 100% pretreated fresh or outside air with a high Oxygen content supplied via the channel system; The air is in the heat exchangers the respective Treated according to spatial conditions. On the other hand, if the rooms are not in use, the The heat exchanger of the devices is used to heat or cool the room through pure self-convection to reach. In this way, on the one hand, there is optimal draft-free ventilation of the rooms with fresh air achieved. On the other hand, if the room is not used,

, o me only the self-convection of the devices energy-saving exploited to avoid cooling down (e.g. at night). The device according to the invention is therefore advantageous because the closing device the way according to the operational requirements

! 5 shut off for the pretreated air, and at the same time opens the convection airway and vice versa. The device according to the invention can do what the control of the operation are restricted to a minimum of movable parts, while at the same time being ensured is that no transfer of air from one room to another is also connected to the system Space takes place, which is especially due to the prevention of the transmission of infectious agents in Hospitals and schools matters.

The device according to the invention has the further advantage that it has only a few parts which can be designed to be relatively space-saving and space-saving, so that it is particularly suitable for installation in window parapets instead of conventional radiators. The device thus offers a real multi-function function as well as simplification of the system structure (e.g. by eliminating the radiator), saving investment, operating and maintenance costs.
The heat exchanger of the device can be used for heating with common media, such as hot water. Steam or oil be formed, or be operated with electrical energy. It is also feasible to charge the heat exchanger with potash water in order to have a cooling effect for post-loading, if necessary.

to achieve action of the air. With the help of thermostatic control devices, individual heat exchangers or groups of devices can be controlled as required according to the required room temperature.
The device is also expediently characterized in that the locking device is actuated either by auxiliary energy or by the energy contained in the supply air flow.

Advantageously, the device according to the invention is designed so that the locking device a the only switching device is. Such a switching mechanism enables either the release in a simple manner the way for the pretreated air for the ventilation or Air conditioning operation or enabling the Convection air path when the fresh air supply from the preconditioning system is interrupted, wherein at the same time the convection air path or, when the room air path is released, the supply air path is blocked will.

The device can be designed with its airways so

the. that the switching element can be installed without difficulty. The ones with high pressure over that Fresh air brought into the air duct system is relaxed in the device, with the typical air relaxation noises with the help of known soundproofing material installed inside the air conditioning convector is. largely attenuated.

An expedient development of the device is characterized in that the switching element as a

Interchangeable flap is designed with roller segment shape, which when the ballast is switched off due to spring and / or gravity, the supply air path is closed and the room air path designed as a convection air path keeps open and when the system is started up against the force of spring or gravity with the help of the im Supply air flow contained slrömungs- or pressure energy, the supply air path open and the convection air path keeps closed.

This development makes the device according to the invention particularly suitable for use in laboratories, Schools or hospitals, as this is an impermissible or even more dangerous due to the risk of contamination Air exchange through air ducts to other rooms is prevented. That after the further training executed device meets the above requirement, because the interchangeable flap is backwards Makes air circulation impossible and works particularly trouble-free, because the movement of the interchangeable flap With the help of the energy of the fresh air flow, we are automatically controlled by auxiliary energies and by complex, as well as failure-prone control organs is independent.

An additional improvement in the mode of operation of the device according to the invention is characterized in that that the free cross section of the air outlet opening by means of the air outlet speed can be reduced in size during the mechanical ventilation operation accelerating cover device. It is advantageous that the cover device as a pendulum flap that can be aerodynamically actuated by the mechanically generated air flow is formed, and that the pendulum flap is automatically activated by spring or gravity when the mechanical air flow is interrupted is resettable.

This additional device improvement allows the warm convection air flow slowly rising in the device a sufficiently large unthrottled outlet cross-section free, while with the activation of the mechanical Ventilation as a result of the increased air velocity energy, the intended reduction in cross section is achieved, which is particularly desirable when the window parapet is very deep must be supplied with fresh air. By simply adapting what is required for fan operation The size of the air outlet opening can be the favorable air outlet speed corresponding to the depth of the room, etc. can be set.

An embodiment of the invention is described below with reference to the drawings. It shows

F i g. 1 shows a section through an air conditioning convector according to an embodiment of the invention with a Interchangeable flap in the shape of a roller segment, which can be actuated against gravity by a medium impulse is,

Fig. 2 is a perspective view of the interchangeable flap in roller segment form. as it is used in the air conditioning convector according to Fig.l and

F i g. 3 a pendulum flap, as it is in the air conditioning convector according to FIG. 1 is provided

The air conditioning convector shown in Fig. 1 has a Housing 1, which at its lower end has an air inlet opening 2 for the fresh air inlet, as well as a Room air opening 3 for the convection air passage contains the housing 1 also has at its upper End of a main opening 4 of the device. The main opening 4 of the device is covered by a grid 5. The room air opening 3 is covered by a grid 6.

Between the inlet openings 2 and 3 and the Ge device main opening 4 is a changeover flap 7 in whale zensegmentform arranged. This interchangeable flap is in its one in the figure shown End position in which the room or convection air is blocked and the supply air is released. Upper half of the interchangeable cap, a heat exchanger 8 is seen before. In the airway from the fresh air inlet port Hung 2 to the heat exchanger 8 is a nozzle bar 9. On the wall of the housing 1 is Sound insulation material 10 attached. Also the Wech Seiklappe 7 contains sound insulation material. Behind the fresh air inlet opening 2 there is an air Storage chamber 11 in which an adjustable balancing or throttle grille 12 is arranged. Below the one in the main opening of the device 4 arranged grid 5, a pendulum flap 13 is provided. If from a ballast pretreated fresh or outside air with high pre-pressure via the duct system at the inlet opening 2 is brought up to one of the devices, then the throttle device 12 initially blocks the air free access to the air storage chamber 11 acting as a pre-expansion chamber and thus reduced in Relatively low air release noise due to the gradual release of the high air pressure. The interchangeable flap 7 is then pivoted by the pressure energy contained in the air in such a way that it clears the airway up to the main opening 4 of the device. The fresh air can then be relaxed at the same time after the nozzle bar 9 into the expansion space 12a and pass through the heat exchanger 8 to the main opening 4 of the device. A post-treatment of the fresh air can take place in the heat exchanger 8 by influencing the temperature. In this way, the air temperature for each room can be included Influence separately with the help of a water-side control device. The interchangeable flap 7 is through the Pressure energy of the fresh air is pivoted so much that it then clears the convection air path between the room air opening 3 and the main opening 4 of the device. This prevents room air from passing through the room air opening 3 is carried away by the fresh air and is also fed to the main opening 4 of the device. Through the The main opening 4 of the device is only used in this operation for the pre-treated and possibly post-treated fresh or Leak outside air. If the fresh air coming from the ballast is switched off, then the Due to its force of gravity, swivel the interchangeable flap 7 into a position in which it provides the fresh air path seals that no room air can pass through the duct system to other rooms. Simultaneously the convection airway is released with this flap position. It can now self convection via the heat exchanger, with the air moving upwards when heating and in the opposite direction when cooling emotional.

In Fig. 2 is the roller segment-shaped interchangeable flap 7. the one in the air-conditioning convector according to FIG. 1 used is shown in detail. This interchangeable flap extends over almost the entire width of the air conditioning convector and is pivotably mounted with the help of two hinges 14 that of the air storage chamber 11 facing side wall 15 of this interchangeable flap can be perforated for better sound absorption Material.

In Fig. 3, the pendulum flap 13 is shown designed so that it is in the Kiima convector according to FIG. 1 over almost the entire width of the

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ters 5 extends. It is on its two opposite end faces in hinges 16 about a pivot axis 17 easily rotatable. On one side of the pivot axis 17 there is a shorter beveled one Part 18, on the other hand a longer flat part 19. The focus is inside of the longer, flat part 19.

In the idle state, i.e. H. when the mechanical air supply is interrupted, the pendulum flap 13 takes a hanging vertical due to its center of gravity Location a. When air is mechanically against the pendulum flap 17, which is in this state, in a vertical position Direction from bottom to top is blown, then the pendulum flap is due to the on the fold 18 acting force initially pivoted a little in the direction of the arrow. The incoming air then also exercises a force on the longer, flat part 19, whereby the pendulum flap suddenly in about is pivoted horizontal position in which it strikes against the grid 5. In this position it blocks part of the device opening 4.

1 sheet of drawings

Claims (10)

Claims. 1. Device / air conditioning b, \\. Temperature control of rooms that have an increased need for pure additional air due to their use, whereby the air is pretreated in an upstream switchgear and conveyed to the ventilating rooms at increased pressure via an air duct system, with a downstream expansion device. which is followed by a heat exchanger and is marked with a reversible closure device which enables the pretreated air to be blown into the room via the heat exchanger or, after switching, also allows convection operation. that the closure device (7) either to completely shut off the pretreated air and / tim simultaneous complete release of the convection Juftweges (3) or / to completely shut off the Konvektionsluftv.eges (3) and simultaneous complete release of the path (2) for the pretreated Air is switched alternately. 2. Device according to claim 1, characterized in that the relaxation device (9) at least a pre-expansion device (2. II) is connected upstream is. in which the air is partially relaxed will. 3. Apparatus according to claim 2, characterized in that the closure device (7) and the heat transfer device (8) are arranged in a common housing. 4. Device according to claim 3, characterized in that the Vorentspannur.gsvorrichtung in is arranged in the common housing. 5. Apparatus according to one as the preceding claims, characterized in that the closure device is actuated either by means of auxiliary energy or by the energy contained in the flow of fresh air. b. Device according to one of the preceding claims, characterized in that the lowering device a single switching element (7) is. 7. Device according to one of claims I to b. characterized in that the ballast downstream expansion device has one or more nozzle strips (9). 8. Apparatus according to claim 6 or 7, characterized in that that the Unischaltorgan (7) as an interchangeable flap with roller segment shape is. the fresh air path when the ballast is switched off due to spring and / or gravity closed and the room airway designed as Konveklionsluftweg keeps open and the at System commissioning against the spring and / or gravity with the help of the fresh air flow contained flow or pressure energy the fresh air path open and the convection air path keeps closed. 9. Device according to Claim 5, characterized in that that the locking device (7) is actuated by the switching pulses for the pre-acoustic system. 10. Apparatus according to any one of claims 1 to 9, characterized in that the free cross section of the Air outlet opening (4) by means of one, the air outlet speed cover device (13) which accelerates the mechanical ventilation operation can be reduced in size. II. Device according to claim 10, characterized in that that the covering device (13) as one is formed by the mechanically generated air flow aerodynamically actuatable pendulum flap and that the pendulum flap (13) by spring and / or gravity when the mechanical intermittent Airflow is reset.