EP3802173A1

EP3802173A1 - Device for a ventilation system

Info

Publication number: EP3802173A1
Application number: EP19728964.8A
Authority: EP
Inventors: Armin Stamm; Eckhard Schwartz
Original assignee: Rheinmetall Landsysteme GmbH
Current assignee: Rheinmetall Landsysteme GmbH
Priority date: 2018-06-11
Filing date: 2019-06-05
Publication date: 2021-04-14
Also published as: DE102018113902B4; CA3103034C; CA3103034A1; DE102018113902A1; US20210162839A1; AU2019284804B2; NZ771754A; KR20210037660A; AU2019284804A1; KR102542741B1; WO2019238485A1

Abstract

The invention relates to a device for a ventilation system. An air-conditioning unit comprising a rear wall (1) is arranged such that it is oriented, with the rear wall thereof, towards the module or space to be ventilated such that it is to be reached from said module or space. An interface (3) for air output is arranged on the rear wall (2), said interface being divided into a plurality of air output points. Said air output points are arranged in different positions on the rear wall (1). Since all of the air output points do not need to be used, means for controlling the air output, which can prevent or enable the air output at the air output points, are associated with the air output points.

Description

DESCRIPTION

Device for a ventilation system

The present invention relates to a device for a ventilation system, as is preferably used in vehicles. The ventilation system is intended to provide conditioned air in the vehicle interior or in other rooms. The device is particularly preferably suitable for use in combat vehicles.

Air conditioning is conventionally implemented by an air conditioner that can treat or cool the air and make the cooled or conditioned air available to the vehicle

Modern vehicles or other areas of application for such a device are of modular construction, so that the air that is made available to the vehicle by the device should be available in different modules. To make this available in various modules, a connection point must be created via which the conditioned air of the device can be supplied to the modules to be ventilated.

For this, a ventilation system is conventionally used, which often consists of multi-part hoses and air channels, which are branched out to the individual modules and which have their origin on the air conditioning unit. The conditioned air of the air conditioning unit is then made available to this ventilation system via the aforementioned interface. The disadvantage here is that the modules which are provided for the air supply must have a uniform interface in order to be able to receive air from the air conditioner. As a result, a uniform position of the interface must be defined, which must be maintained both on the air conditioning unit and on the modules that are to be ventilated.

This disadvantage is to be avoided or at least reduced in the present invention. It is therefore an object of the present invention to provide a device for a ventilation system which can be contacted by interfaces at different positions and thus can supply different modules with air.

This object is achieved with the features of the main claim.

The present invention thus proposes a device for a ventilation system, which comprises an air conditioning device which at least adjoins or partially projects into the module to be ventilated. For this purpose, the air conditioning unit has a rear wall, which either adjoins the module to be ventilated in such a way that the rear wall is freely accessible from the module or the rear wall projects into the module at least in regions.

An interface for air discharge is now arranged on the rear wall, this interface being divided into several air discharge points. The air discharge points are preferably designed side by side, so that a long row of air discharge points is created. The air discharge points are thus arranged at different positions on the rear wall.

It is now possible to deliver the air to the corresponding module to be ventilated at these air discharge points, which makes it possible to arrange the air inlet to the individual modules at different points on the module, with the requirement that the individual points point to at least one air discharge point device according to the invention are adapted. According to the invention, the air discharge points are provided with means for controlling the air discharge, these means being able to control the air discharge in such a way that the air discharge can be prevented or made possible at the individual air discharge points. Intermediate positions, i.e. a reduced air release, are also conceivable here.

In the simplest form, these means for controlling the air discharge can consist of plates which can be arranged at the individual air discharge points. The plates are arranged so that the air discharge points can be closed by the plates. With the aforementioned long series of air discharge points, it is therefore advisable to close the air discharge points not required for air discharge by appropriate means for controlling the air discharge and to open the others accordingly by removing the means.

Air ducts can be connected to the air discharge points, which can direct the air discharged from the air conditioning unit into the module provided for ventilation. According to the invention, these air ducts can be designed differently.

In one embodiment, the air duct is designed as a ventilation shaft. This ventilation duct is rigid and made of solid materials such as plastic or metal. The ventilation shafts are designed so that they lead the air from the air conditioning unit used to the corresponding point in the module.

The air duct can also be designed as a hose, which can also be made of plastic or a textile, for example. Compared to the ventilation shafts, this form of air routing has the advantage that it can be placed more flexibly in the areas in which the air discharge is to take place.

The means for controlling the air delivery can be operated manually, for example as mentioned above, by attaching or removing plates. In a particular embodiment, however, the means for controlling the air delivery are designed in such a way that the corresponding means are actuated automatically when the air duct is connected. This means that when the air duct is connected, the air discharge is automatically released, so that an air supply to the air duct is made possible and that when the air duct is removed, the respective air discharge points are automatically closed so that air discharge is prevented.

So that the air from the air conditioning system can be supplied to the module to be ventilated and can also be discharged there, it is proposed that the air duct have at least one air outlet. The air outlet can be designed so that it is always open. But it can also be designed so that the air outlet is controllable. This means that means for regulating the air outlet are provided, which can regulate the air flow at the air outlet. The air flow can also be stopped entirely. Any position between these two options is possible.

It is proposed to design the air outlet, for example, from air-permeable textile or, in order to implement the aforementioned regulation, from at least one ventilation grille. This ventilation grille can then e.g. regulate the air flow with a slider as mentioned above. The slider can be automated, i. H. can be controlled electrically or manually using a mechanical lever.

In order to be able to maintain the device in the installed state, it is proposed to provide at least one maintenance flap on the rear wall of the air conditioning unit. Maintenance work can then be carried out on the air conditioning unit through these maintenance flaps. The maintenance hatches can also be designed so that people can climb through them. This is recommended for very large air conditioning units.

In a further preferred embodiment it is proposed, when using the ventilation shafts, that these have fastening points. Additional elements of the air control, such as an air distribution, could be attached to these attachment points. The attachment points can also be used to attach the ventilation shafts themselves in the module to be ventilated. The aforementioned attachment points can be realized by simple screwing, but locking and gluing are also conceivable.

Since the air delivery to several modules should also be possible, it is proposed to provide the device according to the invention with an extension. The extension is not located on the rear wall of the air conditioner, but outside of it. For this purpose, the extension has further air discharge points, which is preferably also designed as a row next to one another. So that these air discharge points can also allow their air discharge, the extension is connected to the air conditioning unit, preferably by a duct. This passage can be rigid or flexible and it can be connected to a specially provided connection of the air conditioning unit or at the aforementioned air discharge points on the rear wall of the air conditioning unit. This makes it possible to allow air distribution even in modules that are sealed off from the rear wall.

For example, the air supply could be desired in two different modules in a vehicle, the two modules being isolated from one another. In this case, an air supply would then be made possible in the first module by the air discharge points on the rear wall of the air conditioner, and the air supply would be ensured in the module that was sealed off from it by the expansion.

Furthermore, it is proposed to arrange an air distribution on the air duct in a special embodiment. This can, for example, be fastened by the fastening points or else be firmly connected to the air duct. For example, it is possible to implement roof ventilation. For this purpose, an air duct is connected to at least one air discharge point and an air distribution is assigned to the air duct. The air distribution is then arranged on the ceiling of the module to be ventilated and also has at least one air outlet. As mentioned above, this can be realized from air-permeable textiles or corresponding other air-permeable elements. It is also particularly preferred to assign a closable opening to the air distribution. As a result, a stronger air flow can be generated selectively in the module to be ventilated. The closable opening can be realized by flaps or, in the case of a textile-like air distribution, by areas each with a zipper.

An air conditioning device, which processes the cooled air before it is released to the module to be ventilated, can also be assigned to the air conditioning device. ABC filters are conceivable, for example.

For a better adaptation of the various modules to the air discharge points, it is proposed to divide the interface with the individual air discharge points into a grid dimension, so that the air discharge points are arranged in defined positions.

The various options for air delivery and the various types of air routing have created a multitude of options for ventilating the corresponding modules. Not only can air be directed to different locations in modules to be ventilated, it also enables active ventilation of seats in a vehicle.

Further features emerge from the drawings. Show it:

Figure 1 is a perspective view of the device using

Ventilation shafts;

Figure 2 is a perspective view of the device using a

air distribution

In Figure 1, the device according to the invention for a ventilation system is shown, here the air conditioner that is used is shown with a rear wall one, the rear wall 12 to the module to be ventilated An interface 3 is arranged on the rear wall 1 and is used to release air from an air conditioning device.

However, the interface 3 is divided into air discharge points, which are preferably arranged next to one another, so that the interface 3 forms a long row. The air discharge points and the interface are thus arranged on the rear wall of the air conditioner.

Furthermore, the air discharge points have means for controlling the air discharge, which means can prevent or enable the air discharge at the individual air discharge points. An intermediate position is also possible.

Air ducts 11 can be connected to the individual air discharge points. In FIG. 1, air ducts 11 are shown as ventilation shafts 4. The ventilation shafts 4 are arranged at different air discharge points, so that air can be directed from the air conditioning device through the ventilation shafts 4 to different locations in the module to be ventilated.

Means are provided for controlling the air delivery so that the air delivery only takes place at the air delivery points used and thus no air flow takes place at the air delivery points that are not used. These can be operated manually or automatically.

Manual operation means that the individual air discharge points can be blocked or released manually. In its simplest form, this is possible by means of plates which are arranged at the air discharge points. Automatic actuation is possible, for example, in that the control means are arranged at the air discharge points in such a way that when the air duct is connected, they release the air discharge points and block them when they are dismantled. For simple maintenance of the air conditioning unit, it is proposed to provide the rear wall 1 of the air conditioning unit with maintenance flaps 2, so that the air conditioning unit can also be reached from the module to be ventilated in order to maintain it. The maintenance flaps 2 proposed for this purpose are arranged on the rear wall 1 of the air conditioning unit.

The air ducts 11, in this case shown as ventilation shafts 4, preferably have an air outlet 5. This can consist of air-permeable textile. In the present embodiment as ventilation shafts 4, however, it is proposed to use at least one ventilation grille as air outlet 5. This has the advantage that the ventilation grille can also be controlled and this can enable or block the air flow through the ventilation grille. Intermediate positions are also conceivable here.

As a mounting aid, the ventilation shafts 4 preferably have fastening points 6, via which the ventilation shafts 4 can be attached in the module to be ventilated. Other air distributions 9 can also be fastened to the ventilation duct 4 via the fastening points.

Also shown is an extension 7 of the device according to the invention, via which air discharge points can also be provided in modules which do not reach the rear wall 1 of the air conditioning device. For this purpose, the extension 7 is inserted in the module to be ventilated and is preferably connected to the air conditioning unit via a duct 8. As a result, the air supply can not only be supplied to a module via the air discharge points in the rear wall 1 of the air conditioning unit, but also via the air discharge points of the extension 7.

Figure 2 also shows an air distribution 9, which is also connected to the rear wall 1 with the air conditioner and which realizes the air supply via an air duct 11.

This air distribution 9 can be used, for example, to reach other areas in the vehicle. This means that the air can also be used for seat ventilation. It is preferably proposed to realize the air distribution 9 from textile, in which case the air outlet 5 can be reached by air-permeable material.

Furthermore, closable openings 10 are proposed, which can be assigned to the air distribution 9. This can be used to selectively increase the air flow at certain locations. It is shown in FIG. 2 that the openings 10 can consist of zippers. These can be opened when in use, so as to generate a stronger air flow, or can be closed so that no air flows through the openings 10. The present invention is not limited to the aforementioned embodiments. Rather, further embodiments are conceivable. This makes it possible to connect branched air ducts to the device in order to reach more locations in the module to be ventilated. Likewise, the air discharge points could be circular instead of rectangular.

LIST OF REFERENCE NUMBERS

1st back wall

2. Maintenance hatch

3. Interface

4. Ventilation shaft

5.Air outlet from 4

6. Attachment point

7. Extension of 3

8. Pass-through

9. Air distribution

10. Opening

11. Airflow

Claims

1. Device for a ventilation system,

with an air conditioner which comprises a rear wall (1),

wherein an interface (3) for air discharge is arranged on the rear wall (1),

that the interface (3) is divided into several air discharge points,

that the air discharge points are arranged at different positions on the rear wall (1)

and that the air discharge points are assigned means for controlling the air discharge, which can prevent or enable the air discharge at the air discharge points.

2. Device according to claim 1, characterized in that the means for controlling the air discharge consist of plates which can close the individual air discharge points.

3. Device according to claim 1 or 2, characterized in that at least one air duct (11) can be connected to the air discharge points.

4. The device according to claim 3, characterized in that the air duct (11) is designed as a ventilation shaft (4).

5. Device according to one of claims 1 to 4, characterized in that the means for controlling the air delivery can be operated manually.

6. Device according to one of claims 3 to 5, characterized in that the respective means for controlling the air discharge with connected air ducts (11) are actuated automatically.

7. Device according to one of claims 1 to 6, characterized in that at least one maintenance flap (2) is arranged on the rear wall (1).

8. Device according to one of claims 3 to 6, characterized in that the air duct (1 1) has at least one air outlet (5).

9. The device according to claim 8, characterized in that the air outlet (5) consists of air-permeable textile.

10. The device according to claim 8, characterized in that the air outlet (5) consists of at least one ventilation grille which can regulate an air flow.

11. The device according to one of claims 4 to 10, characterized in that the ventilation shafts (4) have fastening points (6).

12. Device according to one of claims 1 to 11, characterized in that the interface (3) by at least one extension (7) provides additional air discharge points, which can be arranged outside the rear wall (1).

13. The apparatus according to claim 12, characterized in that the extension (7) is connected to the air conditioner by a passage (8).

14. Device according to one of claims 1 to 13, characterized in that an air distribution (9) is arranged on an air duct (11).

15. The apparatus according to claim 14, characterized in that at least one closable opening (10) of the air distribution (9) is assigned.