The invention being submitted pertains to air-conditioning devices for rooms, particularly for hotel rooms or hospital rooms.
Air-conditioning appliances with processing systems and air-discharge systems are familiar. Such air-conditioning devices are used particularly in hotel rooms, whereby the outgoing air is being again extracted via the adjacent sanitary block. The disadvantage of many known air-conditioning devices is the high noise generation of the technical systems, as well as the inevitable emergence of draft caused by the air-flow volume and discharge location point, a fact which often prompts guest complaints regarding comfort. Other known air-conditioning devices, that avoid draft-generation, are thermal-inert and react slowly to load deviations, or individual desires for modifications, respectively.
It is hence an objective of the invention being submitted to eliminate the above-indicated disadvantages of known air-conditioning devices. Noise development shall be reduced to a minimum, whereby a sound-intensity level of 20 dB(A) is intended to be achieved in the room. Drafts of any kind will be avoided for the benefit of the hotel guest, and the hygienic conditions for the guest will be improved. At the same time, the equipment installation is intended to be effected quite simply.
This problem will be solved by means of a bed pursuant to Claim 1, a wet-cell pursuant to Claim 25, respectively a room pursuant to Claim 34. The dependent claims pertain to advantageous layouts of the invention.
A central element of the invention is the feeding of air into the hotel room through the required and thereby existent bedstead. Corresponding to the room volumes, the air supply is alternately heated or cooled via lateral outlet orifices located in the bedstead, and thus fed, draft free, into the room, or blown directly over the bed's mattress by means of an integrated switchover mechanism. With the term bedstead side walls, not only bedstead longitudinal walls are thereby meant, but also the walls at the foot-end and/or the head-end. The advantage of the air being supplied over the bed is predominately attributed to the consistency of the air current, so that with little draft emergence and minimal noise generation, a high air supply is possible.
The air supply into the room which flows through the mattress provides the possibility of heating, resp. cooling the mattress via room air-conditioning. Additionally, the mattress can be so dried in order to reduce, resp. eliminate mite formation. If the air supply comes with desinfectant, even the build-up of bacteria in the mattress can be excluded, so that the room conditions are yet suitable for extremely sensitive allergic persons.
In a wet-cell according to the invention, the air-conduction conduits are integrated in the walls and preferably equipped with a noise suppression, so that any generation of noise is reduced to a minimum.
The presented invention will in the following be explained in detail by means of preferred layout—examples of operation with reference to the enclosed drawings.
Furthermore, beneath the mattress 2 and the rack 9, is a mattress air-chamber 10 with additional upper escape ports 8, so that the additional air can be blown directly over the bed's mattress 2 (mattress-airing operation). By means of special shoulder-banding, resp. contact-pressure profiles 17 and the arrangement of the individual jets in a chamber plate, it is being safeguarded that no air loss occurs over the lateral edges of the mattress. For the separation of side airflow, the mattress air-chamber 10 has a chamber plate with adjustable individual jets, resp. distribution rails. As will later be more precisely described, the additional air can either be only laterally blown out of the bedstead 1 via an integrated switchover unit 16, or only over the mattress 2, or both simultaneously.
Preferably intended are the functions: “Room flow air-source operation”, “Mattress flow cooling-resp. heating operation”, “Mattress-drying operation” and “Mattress-desinfection operation”.
In air-source operation, the additional air will be blown off via the lateral escape ports 5. Through the large lateral surface of the bedstead 1, with a relatively high number of escape ports 5, a very consistent room air-flow is obtained. Furthermore, due to a low discharge speed, a minimal noise rate is being achieved at fastest possible heating-, resp. cooling of the room.
With the mattress air-flow function, the cooled-, resp. heated air is blown off over the mattress 2. This can be pleasant for the guest to cool or warm the bed, while sleeping in summer-, or winter periods respectively. For maximum comfort desires, beyond that, provisions exist for pre-warming, resp. pre-cooling the bed.
The air-source operation and the mattress air-flow function can also be run simultaneously. For the person lying on the bed, this has the effect of being supplied—turbulence- and pollution-free—with cooled or slightly warmed air. Absorption of harmful substances via air turbulence is therefore minimized. The results are very good air quality in the laying area. In connection with the mattress air-flow function, maximum air quality is achieved, which is even suitable for allergic persons.
In the drying function for the mattress 2, an airflow through the mattress also takes place. Thereby, the air can be processed, resp. air-flow parameters will be employed, in order to dry the mattress following sleeping periods, preferably during guest's absence. The danger of mite accumulation in the bedding will in this way be reduced, which poses a considerable problem in hotels.
In the mattress-desinfection operation, a mattress flow likewise results. During this process, the air can be treated with a desinfectant in order to desinfect the mattress 2 following its occupancy, preferably in the guest's absence. By doing this, the control of bacteria accumulation in the mattress 2 and other hygienic requirements will be taken into account. Of course, the desinfection operation can also be implemented simultaneously along with the drying operation. For the desinfection operation, a desinfection device can be accommodated in the bedstead, which offers service personnel the possibility to attend to the mattress 2 of the respective bed with regard to aseptic control.
As reflected in
The air-feed into a distribution-chamber 14 if effected either from the head section of the bed through a distribution-duct installed in the furniture or in the partition wall, or via special air-discharge outlets integrated in the floor structure. Using adapters, moving of the bed to a certain extent can also be realised. On the bedstead 1 head-end, via a side-duct air-inlet connection 7, the distribution-chamber 14 is combined with the side-ducts and with the mattress air-chamber 10 via a mattress air-chamber-feeding connection 11.
The switchover in the distribution-box is effected via one or several, preferably joint-functioning, sliding flaps 15 for all connections. The various options of the additional-air inlet in the room can thereby be effected alternately. By means of an integrated switchover-unit 16, the additional air can thus either be blown-out merely laterally from the bedstead 1, or only over the mattress, or both simultaneously.
Accordingly, switchover can also be effected between the setting conditions “room flow air-source operation”, “mattress flow cooling/heating operation”, “mattress desinfection” and “mattress drying”. To enhance sleeping comfort, control of the switchover unit can thereby be automatic, but also individual at the guest's desire. The automatic control can thereby be activated through a detection system, that recognizes whether the hotel-room guest is in his room (presence-switching) or absent (absence-switching). Such detection system, that may be fitted into the door area, can, for example, sense whether the guest enters or leaves the room. It is, however, also possible that the switchover be effected via the hotel reception.
The special feature of the air conduction within the wet-cell can be noted in the conduction of the additional-air and the exhaust in special, sound-absorbing conduits, which are accommodated in the cavity of the wet-cell walls. With these ducts, the necessary high noise-suppression ratings will be accomplished.
The air-treatment for an air-conditioning facility can be effected, according to the invention submitted, in the ceiling area of the wet-cell or in the ceiling section of the room-access corridor.
The supply of the individual guestroom normally takes place with processed primary-air, which meets requirements of air conditioning, via a conventional central system. The primary-air will be exactly regulated through setting devices (mechanical or electronic volume-flow regulators), precisely lined up in the secondary-air treatment unit, which is preferably located in the wet-cell ceiling area, fed via a primary-air duct.
The primary-air system is always available based upon the possibility of utilization of heat-recovery. An economical supply with sufficiently high exterior-air rate per hotel-room is thus assured.
From the secondary-air treatment unit, via an additional-air duct located in one of the wet-cell walls, the conditioned air will be fed to the bedstead subject to the invention submitted. After the discharge, a portion of the displaced room-air will again be fed to the secondary-air treatment unit. Backflow of the secondary-air occurs in a special exhaust duct located in the wet-cell wall, which warrants both for the entire through-flow of the room as well as the necessary acoustic properties. Filtering of the room-air is effected during this stage of the induction process. This enables convenient maintenance without the intermediate ceiling having to be opened. By means of the special arrangment of the induction, filter exchange can be implemented near the floor in the corridor and thus without having to open the ceiling in the wet area. Another portion of the displaced room-air is conventionally extracted from the wet-cell via an exhaust duct (not shown), and blown out through the roof.
The reduction of heat-attenuation ratings of the wall between guestroom and wet-cell to be anticipated, due to installation of the air-conditioning conduits 20 in the wet-cell partition walls 19, will in one way be accounted for by duct attenuation and also through the special heavy, rubber-mat casing outside the additional-air duct. Aside of the additional air-side noise attenuation, this arrangement simultaneously effects the heat insulation in both heating- and cooling operation. The air-treatment device can be designed as special sound-absorption construction with interchangeable connector box, so that all conceivable connection options are possible.
The air-conditioning system pursuant to the invention can be constructed as an integral functional principle, whereby technical function and design of all components enable their coordination with one another. The aggregate advantages of the individual components become fully effective only in the composite structure of all components.
The wet-cell with integrated air-processing unit, resp. air-treatment unit 18, can be supplied completely pre-installed, including ready-wired electric sub-distribution and pre-installed room-air system with special acoustic silencing, which gains additional muffling through laying the air feeding and discharge ducts in the partition wall of the wet-cell. This yields a substantial reduction of installation period and failure sources. Another advantage is that all components can be factory checked and acceptance-tested. Likewise, it is possible to deliver the air-conduction-, or bed air-discharge systems respectively, in prefabricated condition. The subject system pursuant to invention is therefore particularly suitable for restauration purposes.
The secondary-air processing unit, or the secondary-treatment device respectively, for the individual room unit consists of a complete acoustically decoupled unit, which is integrated, ceiling-flush, in the upper section of the wet-cell or in the door area next to the wet-cell. The unit serves for heating and cooling and is being additionally supplied via a primary-air connection with processed exterior air from the central system. Based upon the excellent noise attentuation and the particular in- and outflow conditions, higher delivery pressures can be achieved, which, among other things, are used to also install the circulating-air operation filter (class F5) in the room. The secondary-air processing unit, or the secondary-treatment device respectively, is subdivided into several performance sizes and can be both installed, prefabricated in the wet-cell, as well as without wet-cell, set-up in the corridor.
Number | Date | Country | Kind |
---|---|---|---|
201 13 291 U | Aug 2001 | DE | national |
201 13 292 U | Aug 2001 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP02/07438 | 7/4/2002 | WO | 00 | 6/26/2004 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO03/014630 | 2/20/2003 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
1142876 | Davis et al. | Jun 1915 | A |
3266064 | Murray | Aug 1966 | A |
3601031 | Abel et al. | Aug 1971 | A |
3928876 | Starr | Dec 1975 | A |
4218791 | Itoku | Aug 1980 | A |
4505328 | Schmitt | Mar 1985 | A |
4667580 | Wetzel | May 1987 | A |
4835983 | Chandler et al. | Jun 1989 | A |
5416935 | Nieh | May 1995 | A |
5887304 | von der Heyde | Mar 1999 | A |
6336237 | Schmid | Jan 2002 | B1 |
Number | Date | Country |
---|---|---|
86 00 552 | Jun 1986 | DE |
2000 018638 | Jan 2000 | JP |
Number | Date | Country | |
---|---|---|---|
20040253920 A1 | Dec 2004 | US |