DE102015104375A1 - carrier - Google Patents

Abstract

The invention relates to a carrier, in particular profile carrier, with at least two profile elements connected to each other at an angle, in particular at least one belt and a web. It is provided that at least one of the profile elements of a pattern core plate, in particular of a honeycomb core plate, each with two cover plates and a structural core arranged therebetween, in particular, is formed. The invention further relates to a clean cabin, whose side walls are made of structural core plates and in the carrier, which are at least partially formed from structural core plates, are installed. The use of structural core plates for the construction of the carrier and the clean cabin leads to a lightweight and durable construction.

Description

The invention relates to a carrier, in particular profile carrier, with at least two profile elements connected to each other at an angle, in particular at least one belt and a web.

The invention also relates to a clean gas cabin with a sealed environment from the surrounding, surrounded by side walls interior.

Profile beams are known in different design. Typical embodiments are T-beams and double-T beams, but beams with U, C and angle profiles. Such carriers are composed of at least one upper and / or lower cross member (belt, also referred to as a flange) and a central part (web). The bridge is firmly connected to the strap (s) at an angle. For this purpose, the web and the or the straps may be made in one piece or be connected to each other by suitable joining techniques, in particular by welding, riveting or screwing. The profile of profile beams usually remains the same over their length.

Due to their profile, such carriers receive a high bending resistance moment. Thus, they are suitable for receiving high loads, for example in supporting structures or substructures of buildings or housings.

Typical materials for such profile beams are structural steels, as they are for example in the Standard EN 10025 are fixed. To save weight, aluminum supports are also used.

From the DE 624855 Profile beams are known whose webs and flanges are made of plywood strips. This plywood strips stump against the broad side of the adjacent plywood strips. The corners between the adjacent plywood strips are covered with veneer strips whose fibers are oriented obliquely (eg 45 °) to the longitudinal axis of the carrier. The veneer strips are bent under adaptation to the profile of the carrier and glued to the respective web and flange. By this construction, a load-bearing profile carrier is obtained.

For many applications are disadvantageous known and resilient carrier, even when using light metals or plywood, comparatively difficult. They thus contribute even to a high mechanical load on their contact points and their site. For special applications in which, for example, no gas should penetrate through the carrier or which are intended for rooms with high requirements in terms of cleanliness (clean room) or the atmosphere, plywood carriers are not suitable.

Numerous manufacturing processes and work steps in production as well as in research and development can not be carried out under normal environmental conditions, but require a separate atmosphere. Such manufacturing processes can be coating processes, for example in semiconductor production, encapsulation steps in LCD or OLED production or production processes of highly pure base materials, for example in medical and pharmaceutical technology. For example, the processes may require clean room conditions, low humidity, an inert gas atmosphere, or a combination of various such and other conditions.

It is known to carry out such manufacturing processes or operations in a closed room in which the atmosphere can be adjusted according to the required conditions. The closed room has locks, through which the required materials can be introduced into the enclosed space and the products can be removed.

Such a space is formed, for example, in so-called glove boxes, as they are adequately described in the literature (cf. "Cleanroom technology", 3rd updated u. ext. Ed., Springer, pp. 202-207 ). Such gloveboxes are mainly made of stainless steel. They offer the possibility to carry out the desired working steps within the glovebox via glove feedthroughs. To set the required atmosphere corresponding gas supply lines or circulation lines, with which the glove box taken gas, passed through at least one gas treatment unit and then fed back to the glovebox provided. Due to their construction, such gloveboxes, especially for large production units, are difficult to integrate into production lines, since the systems to be enclosed can only be introduced into the glovebox via the intended locks.

Therefore, inert gas housings in a hood design are known. The hoods form with a base plate an enclosed space in which the required atmosphere can be adjusted. The pre-assembled hood is placed on top of the base plate and sealed. Required bushings, locks, upstream chambers and other required units and assemblies are preferably already mounted and tested on the hood. The inert gas housing can therefore be quickly placed at a designated work or production place. The approach of the hood design offers the possibility to operate any plant or plant parts in a closed room, whose atmosphere can be adjusted according to the requirements. This is the Size of the hood adapted to the respective system. The materials used to construct the inert gas housings are designed so as not to alter the atmosphere inside them, for example due to contamination or outgassing. Furthermore, the enclosure is designed such that no gas exchange between the interior of the inert gas housing and the environment takes place. Inert gas housing made of stainless steel or aluminum are known. For receiving and storing, for example, heavy aggregates carrying structures can be provided from profile carriers in the inert gas housing. A disadvantage of such inert gas housings is their high weight, which results from the described design and the materials used. The high weight on the one hand makes it difficult to put the hood over the respective system from above, because correspondingly load-bearing lifting devices must be present. In addition, the inert gas casings increase the soil load in addition to the enclosed plant. This makes extensive and costly conversion measures to increase the static of the soil required for insufficient floor load capacity of the building in which the clean gas cabin is to be set up.

It is therefore an object of the invention to provide a lightweight and durable carrier, in particular profile carrier.

It is a further object of the invention to provide a clean cab for receiving facilities or equipment parts whose interior is sealed from the environment whose atmosphere is adjustable according to the requirements for the operation of the system or plant components and which has a low weight.

The carrier-related object of the invention is achieved in that at least one of the profile elements is formed from a structural core plate, in particular from a honeycomb core plate, each with two cover plates and a structural core arranged therebetween, in particular honeycomb core.

Carriers made of structural core plates have a significantly lower weight compared to solid carriers with comparable mechanical load capacity. Due to the structure of the structural core plates with two spaced cover plates, which are interconnected via the structural core, results in a very high bending capacity of the profile elements as such. By joining at least two profile elements, of which at least one, preferably both, are made of structural core plates to a profile support a significant increase in the bending stiffness is achieved, so that a highly resilient and at the same time lightweight carrier is obtained. Structural core plates are gas-tight due to the cover plates arranged on both sides in accordance with the permeation properties of the cover plates used in the direction of their surface normals. The structural core prevents gas within the structural core plate from flowing across its surface normal. This ensures that no gas, for example via the edges of the structural core plates or via apertures introduced into the cover plates, passes through a carrier or within a carrier, for example into a clean space constructed with the carrier.

A particularly lightweight, stable and at the same time gas-tight carrier can be obtained by the fact that the at least one profile element is formed from an aluminum honeycomb core plate. Aluminum behaves advantageously inert to most atmospheres, so that the carrier has a long life expectancy even when used in aggressive environments, without changing the atmosphere.

According to a preferred embodiment variant of the invention, it may be provided that at least two profile elements of the carrier are connected via at least one connection angle and / or that a side leg of the connection angle is connected to a profile element and a second side leg of the connection angle with a further profile element of the carrier. A profile element, for example a web, may preferably rest at an angle of 90 ° with an edge on a surface of a second profile element, for example a belt. The connection angle is then arranged with its side legs on the profile elements and connected thereto. In order for a firm bond between the at least one web and the at least one belt is obtained, wherein the profile elements are held by the connection angle in their mutual position. By connecting the profile elements with the at least one connection angle, a load-bearing carrier is formed. Preferably, two opposite connection angles are provided laterally of a joint between two profile elements. This avoids that a connection angle bends in a one-sided load of the carrier along its bending angle. The one or more connection angles extend in the direction of the longitudinal extension of the carrier preferably over a longer portion of the carrier. It is particularly advantageous if the connection angles extend over the entire length of the carrier.

Advantageously, it may be provided that the at least one connection angle is arranged along an inner angle or outer angle formed between the profile elements. It can be prepared as a variety of known carrier profiles with structural core plates as profile elements.

A highly loadable yet lightweight connection between the at least one connection angle and the profile elements to be connected therewith can be achieved by adhering the at least one connection angle to the profile elements to be connected. The adhesive connection is simple and inexpensive to produce. By a suitable choice of adhesive and the largest possible adhesive surface, a permanently resilient connection can be achieved. Advantageously, the cover plates of the structural core plates need not be broken, as is required for example for receiving fasteners, such as screws or rivets. This preserves the high load capacity of the structural core plates.

A support with a high moment of resistance and thus a high load-bearing capacity can be obtained by designing the support as a T-beam or as a double T-beam or in that the support is a U-profile or a C-profile or a Z-profile or an L-profile or that the carrier is designed as a square tube. The profiles can be constructed simply from flat structural core plates, which due to their construction can not be bent in their total thickness. In one embodiment of the carrier as a square tube connecting angle are preferably arranged along the four corners of the square tube

A simple and cost-effective production of the carrier is made possible in that at least two profile elements of the carrier are formed from a common structural core plate, that along a joint edge between the profile elements, a cover plate of the structural core plate bent and the other cover plate and the structural core are separated, that along the impact edge formed gap in the split cover plate and in the structural core is covered by a connection angle and that the connection angle is connected with its side legs each with the severed cover plate on both sides of the gap. Preferably carrier profiles, which have an external angle between the profile elements, can be produced in this way. Due to the non-separated cover plate one side of the profile elements is already connected, so that a connection angle can be saved. The non-severed cover plate can be arranged on the side of the inner or outer angle. The connection angle is then arranged on the respective opposite side. If the non-severed cover plate forms the inner angle, the gap is bent open on the severed cover plate and the severed structural core during bending of the non-severed cover plate. It is covered by the connection angle, whereby the angle between the profile elements is stabilized. If the cover plate which has not been severed forms the outside angle, it is advantageous if the material of the severed cover plate and the structural core is removed along the gap so that it is not compressed during bending. In this arrangement, the gap closes when bending. Again, the gap is covered by the connection angle and the angle between the profile elements stabilized.

The object of the invention relating to the clean cistern is achieved in that at least a part of the side walls of the clean cask are formed from one or more structural core plates, in particular one or more honeycomb core plates, each having two cover plates and a structural core, in particular honeycomb core, arranged therebetween the clean cabin provided carrier profile carrier with at least two interconnected at an angle profile elements, in particular at least one strap and a web, and that at least one of the profile elements of a structural core plate, in particular a honeycomb core plate, each with two cover plates and a structural core arranged therebetween, in particular Honeycomb core, is formed.

A clean cab according to the present invention is a housing in which a required atmosphere can be adjusted. For this purpose, the housing is constructed gas-tight against its environment. Within the housing manufacturing processes and operations can be performed, which require a separate atmosphere. For this purpose, corresponding production units, such as a robot, or laboratory structures are arranged within the clean cabin. The requirements of the atmosphere may concern their cleanliness, their moisture content or their composition. For example, certain processes can only be carried out under an inert gas atmosphere. Other parameters, such as temperature, may also be adjustable. The clean cab are therefore assigned to corresponding gas treatment units. The clean gas cabin can thus be a cabin with a polygonal base area and an environment sealed by the surrounding walls, with at least one circulation line, taken from the clean gas cylinder, passed through at least one gas treatment unit and then fed back to the clean cabin becomes.

Sidewalls and structural core panels have a significantly lower weight compared to solid sidewalls and girders with comparable mechanical strength. Due to the structure of the structural core plates with two spaced cover plates, which are interconnected via the structural core, results in a very high load capacity of the side walls and the carrier. Structural core plates have a high flexural rigidity, so that the sidewalls and supports formed therefrom do not bend under load or bend only slightly elastically. They are due to the cover plates arranged on both sides according to the permeation properties of the cover plates used in the direction of their surface normal gas-tight. In particular, aluminum honeycomb core plates, in which the cover plates and the structural core are formed of aluminum, are suitable for the production of gas-tight side walls and carriers of the clean cabin. The structural core prevents gas within the structural core plate from flowing across its surface normal. This ensures that no gas, for example via the edges or via openings introduced offset into the cover plates, can enter the clean gas cabin or flow out of the clean gas cabin. It is thus obtained a gas-tight, light and stable clean cab.

Advantageously, the clean cab has at least one of the carriers described above, in which at least one profile element consists of a structural core plate.

The weight of the clean cabin can be further reduced in that a bottom of the clean cab is formed from one or more structural core plates, in particular honeycomb core, running bottom plates and / or that the clean cab is closed at the top by a lid formed from at least one cover plate and that the cover plate is formed from a structural core plate, in particular honeycomb core plates. Due to the high bending stiffness of the structural core plates, a firm floor, but also a walk-in cover of the clean cabin can be obtained.

In order, for example, to be able to store heavy assemblies and components, for example a gas conditioning unit, inside the clean cabin, it may be provided that a support structure is formed from a plurality of supports and that the support structure is fastened directly or indirectly to the side walls. Since the carrier formed at least partially from structural core plates can have a low weight, a comparatively lightweight but nevertheless load-bearing support structure can be constructed. The total weight of the clean cabin remains low.

A simple and attachment of the lid of the clean cab is made possible by the fact that from several carriers a substructure is formed, that on the substructure, the at least one cover plate is fixed, and that the substructure is indirectly or directly attached to the side walls. By using carriers which are at least partially made of structural core plates, the weight of the clean gas cabin can also be kept low in this case.

The invention will be explained in more detail below with reference to an embodiment shown in the drawings. Show it:

1 in perspective external view a clean cabin,

2 in the 1 shown clean cab in a perspective interior view,

3 in the 1 and 2 shown clean cab in an exploded view,

4 a corner of the clean cab in a sectional view from above,

5 one in 3 shown detail with a corner of the clean cabin in a perspective exterior view,

6 one in 3 shown detail with a corner of the clean cab in a perspective interior view,

7 one in 3 shown section with a corner of the clean cabin in an external perspective view and in an exploded view,

8th one in 3 shown section with a corner of the clean cabin in an external perspective view in the region of two connecting rails,

9 two end-to-end side walls with an in 8th shown connecting rail in a sectional view,

10 one in 3 shown section with a vertically arranged connecting rail in an external view,

11 one in 3 shown section with a vertically arranged connecting rail and an upper end of a first vertical side wall in an external view,

12 one in 3 shown section with a vertically arranged connecting rail and a lower end of a first vertical side wall in an exterior view,

13 one in 3 shown section with a vertically arranged connecting rail and a lower end of a fifth and a sixth side wall in an interior view,

14 one in 3 shown section in the area of two adjacent floor panels in an exploded view,

15 a carrier of the clean cab in a perspective view,

16 the in 15 shown carrier in a sectional view looking in the direction of the longitudinal extent of the carrier,

17 one in 3 shown detail in the area of a lid of the clean gas cabin and

18 one in 3 shown section in the field of attachment of a support structure of the clean cab.

1 shows in a perspective exterior view of a clean cabin 10 , For easier transferability of the following designs are a front 10.1 and a back 10.2 the clean cabin 10 freely set.

The clean cab 10 has a polygonal floor plan. In the embodiment shown, the floor plan is hexagonal. On a hexagonal floor 20 are sidewalls 30 established. The side walls 30 are based on positioning elements 21 outside on the ground 20 are attached. In the selected view from the front 10.1 are on the left a first vertical side wall 30.1 and disposed one above the other, a first, a second and a third horizontal side wall 30.8 . 30.9 . 30.10 intended. More vertical side walls 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 are in 3 shown. The first vertical sidewall 30.1 includes a first corner 11.1 the clean cabin 10 , The three horizontal side walls 30.8 . 30.9 . 30.10 span a second and a third corner 11.2 . 11.3 , In the middle area of the second horizontal side wall 30.9 is a section 31 provided in the an intermediate door 35 is used.

At the transitions between the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 are connecting rails 60 provided, which by means of connecting brackets 61 with the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 are connected.

Above is the clean cab 10 with a lid 40 completed. The lid 40 also has a hexagonal basic structure. The area of the lid 40 is made of four cover plates 43 educated. The cover plates 43 are with fasteners 44 and edge fasteners 45 held. Circumferential to the cover plates 43 is a border 42 provided at the a railing 41 is attached.

Laterally at the clean cabin 10 are two circulation pipes 50.1 . 50.2 attached in the form of rectangular channels. The circulation pipes 50.1 . 50.2 are about feeders 51.1 . 51.2 and withdrawal points 52.1 . 52.2 as they are in the 1 . 2 and 3 are shown, with the interior of the clean cab 10 connected. These are corresponding openings in the first and the third horizontal side wall 30.8 . 30.10 as well as in the 3 shown second vertical side wall 30.2 intended.

The clean cab 10 represents a sealed housing to its environment. Inside the clean cabin 10 For example, production equipment or laboratory equipment, etc. can be arranged. Furthermore, in the clean cabin 10 set a predetermined atmosphere. For this purpose, a specific gas or a gas mixture having a predetermined composition in the interior of the clean gas cabin 10 available. The gas or gas mixture may be an inert gas. Furthermore, the humidity of the gas or the gas mixture can be adjusted. As an additional requirement, a required clean room class for the clean cabin 10 be predetermined. The requirements can apply both individually and in combination. In addition, other atmospheric parameters, such as temperature and pressure, can be adjusted. As pure gas according to the present invention, an atmosphere which meets the required requirements, to understand.

Depending on the required atmosphere is the clean cab 10 equipped with appropriate units for providing or generating this atmosphere. In the present embodiment, the clean cabin indicates 10 the two circulation pipes 50.1 . 50.2 on. About these will be at the sampling points 52.1 . 52.2 Gas from clean gas cabin 10 taken and over the feeders 51.1 . 51.2 again the clean cabin 10 fed. The gas becomes an in 2 shown gas processing unit 55 fed. The gas conditioning unit 55 is in connection with the interior of the clean cabin 10 , That in the gas processing unit 55 processed gas becomes after flowing through the gas treatment unit 55 via the sampling points 52.1 . 522 , the circulation pipes 50.1 . 50.2 and the feeders 51.1 . 51.2 the interior of the clean cabin 10 fed. The gas treatment includes the setting for the interior of the clean gas cabin 10 required atmosphere.

The clean cab 10 thus enables the execution of manufacturing processes or operations that require a special atmosphere. Such manufacturing steps can be coating processes, encapsulation processes or the Processing or production of highly pure substances, for example in the pharmaceutical sector, be. The supply of required materials and substances via provided locks, for example, via the intermediate door in the present embodiment 35 , In this case, the intermediate door 35 a connection to one of the clean cabins 10 connected / connected chamber.

According to the invention, the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 made of structural core plates 12 formed as they get closer 4 are described. The side walls can 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 be executed as honeycomb core plates or as aluminum honeycomb core plates. Structural core plates have a multilayer structure. As in 4 shown are at least two spaced cover plates 12.1 . 12.2 flat with a structural core 12.3 connected. The cover plates 12.1 . 12.2 and the structural core 12.3 are made in the present embodiment of aluminum. The structural core 12.3 is designed as a honeycomb core. In this way plates are produced with a high bending stiffness and at the same time a low weight. The clean cab 10 Thus, it has a significantly lower weight than a clean cabin made with solid aluminum or stainless steel walls 10 on. This will reduce the floor load resulting from the weight of the remodeled equipment parts and the clean cab 10 results, significantly reduced. The clean cab 10 can thus also be used in buildings with low floor load capacity. Furthermore, a lighter weight facilitates the installation of the clean cabin 10 at their place of use, as this no lifting or lifting devices are required with a low load capacity.

To the weight of the clean cabin 10 to further reduce are also the cover plates 43 made of structural core plates 12 , formed in the present embodiment of aluminum honeycomb core plates.

2 shows the in 1 shown clean cabin 10 in a perspective interior view. Here, the insight into the clean cabin takes place 10 from the back 10.2 out.

On the ground 20 the clean cabin 10 is along the sidewalls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 a gas supply channel 53 appropriate. The gas supply channel 53 is with the ground 20 and the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 connected. The first feeder 52.1 and the in 3 shown second feeder 52.2 the circulation pipes 50.1 . 50.2 lead into the gas supply channel 53 , This is over perforated grille 54 located on the side and top of the gas supply duct 53 are arranged, with the interior of the clean cabin 10 connected.

Between the horizontal side walls shown 30.8 . 30.9 . 30.10 are connecting rails 60 arranged, which to the interior of the clean cabin 10 in each case an integrally formed hollow profile 60.2 exhibit. The side walls 30.8 . 30.9 . 30.10 lie on the hollow profiles 60.2 at. The structure of the connecting rails 60 the embodiment shown is enlarged and in section in 9 shown.

An upper area of the interior of the clean cabin 10 is through a support structure 70 demarcated. On the support structure 70 is down a blanket 13 attached, which is at least partially designed as a perforated ceiling. On the support structure 70 are filters (and possibly temperature control devices in the form of water-air heat exchangers) 56 the gas processing unit 55 stored. Above the filter (heat exchanger) is a substructure 46 arranged on which the lid 40 the clean cabin 10 is stored. The support structure 70 and the substructure 46 are with straps 80 built on the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 are fixed.

The manufacturing equipment or laboratory equipment etc. can be on the ground 20 the clean cabin 10 be set up. For example, the manufacturing plant or the laboratory structure may be a robot that performs one or more work steps in the set atmosphere of the clean gas cabin 10 performs.

The gas is delivered via the sampling points 52.1 . 52.2 the interior of the clean cabin 10 taken and over the feeders 51.1 . 51.2 fed back to the interior. This is done by the gas through the filters 56 in the space between the ceiling 13 and the lid 40 sucked and then the circulation pipes 50.1 . 50.2 fed. The ceiling 13 is below the filters 56 perforated executed. Alternatively, the ceiling 13 below the filters 56 also be omitted. The interior of the clean gas cabin 10 is thus flowed through from top to bottom of the gas. These are in the circulation pipes 50.1 . 50.2 not shown corresponding fans provided.

3 shows the in the 1 and 2 shown clean cabin 10 in an exploded view.

A fourth corner 11.4 the clean cabin 10 is inside the seventh vertical sidewall 30.7 arranged. A fifth corner 11.5 runs inside the fifth vertical sidewall 30.5 while a sixth corner 11.6 along the third vertical Side wall 30.3 runs. The abutting edges between the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 do not run along the corners 11.1 . 11.2 . 11.3 . 11.4 . 11.5 . 11.6 the clean cabin 10 , They are along rectilinear sections of the outer wall of the clean cab 10 arranged. This allows the transitions between the sidewalls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 be sealed well.

On the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 are fastening rails 71 for fixing the support structure 70 appropriate.

The floor 20 is made of adjoining floor slabs 22.1 . 22.2 . 22.3 educated. In the present embodiment, three floor panels 22.1 . 22.2 . 22.3 intended. To the weight of the clean cabin 10 to reduce, are the bottom plates 22.1 . 22.2 . 22.3 made of structural core plates 12 , formed in the present embodiment of aluminum honeycomb core plates.

The cutouts V . VI . VII . VIII . X . XI . XII . XIII . XIV . XVII . XVIII are in the 5 . 6 . 7 . 8th . 10 . 11 . 12 . 13 . 14 . 17 and 18 shown enlarged.

For the production, the various components of the clean cabin 10 prefabricated. This will be the bottom plates 22.1 . 22.2 . 22.3 , the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 and the cover plates 43 made of structural core plates 12 tailored. Required recesses, such as the neckline 31 for the intermediate door 35 and the withdrawal points 52.1 . 52.2 and feeders 51.1 . 51.2 the circulation pipes 50.1 . 50.2 , be in the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 brought in. The side walls arranged in the corners 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 be along the later corners 11.1 . 11.2 . 11.3 . 11.4 . 11.5 . 11.6 the clean cabin 10 bent, like this too 4 is explained in more detail. The carriers 80 are tailored and to the support structure 70 and to the substructure 46 assembled. The cover plates 43 be with the substructure 46 by means of the fastening elements 44 connected.

For mounting the clean cabin 10 become the floor plates 22.1 . 22.2 . 22.3 to the ground 22 connected and the positioning elements 21 appropriate. The manufacturing plant or laboratory setup will be on the ground 22 positioned. Subsequently, the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 placed and by means of the connecting rails 60 with each other and with the floor panels 22.1 . 22.2 . 22.3 connected gas-tight. Here are the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 one-sided on the positioning elements 21 at. The mounting rails 71 be on the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 attached and the support structure 70 inserted. The aggregates of the gas treatment unit 55 are being installed. Subsequently, the lid 40 fitted and gas-tight with the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 connected. Entrances, like the intermediate door 35 , are mounted. Finally, other assemblies, such as the circulation pipes 50.1 . 50.2 , the gas supply channel 53 , the outline 42 and the railing 41 , appropriate. The procedure offers the advantage that no prefabricated hood must be transported as a whole, but the individual components are installed on site. Hoists are therefore not required and the transport of the components to the site is easy and therefore inexpensive.

In an alternative procedure, first the hood of the clean cab 10 consisting of the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 , the carrying structure 70 and the substructure 46 with the lid 40 , pre-assembled. Depending on the situation, further components and assemblies can be pre-assembled on the hood.

To install the clean cabin 10 becomes the ground 20 constructed, the positioning elements 21 attached to it and set up the manufacturing plant or laboratory setup on it. Subsequently, the preassembled hood from above on the ground 20 established. The advantage here is that the hood can be tested in advance in their function and tightness. Furthermore, the structure can be done quickly on site and thus, for example, without long interruptions of an ongoing production.

4 shows a corner 11 the clean cabin 10 in a sectional view from above. The corner 11 stands for the already introduced corners 11.1 . 11.2 . 11.3 . 11.4 . 11.5 . 11.6 , A structural core plate 12 is made up of two spaced-apart cover plates 12.1 . 12.2 and a structural core 12.3 educated. The structural core 12.3 connects the two cover plates 12.1 . 12.2 , The structural core plate 12 forms the corner 11 out. These are the outer second cover plate 12.2 and the structural core 12.3 according to the invention along the corner 11 separated. The inner first cover plate 12.1 is along the edge 11 bent. Here is the inner first cover plate 12.1 along the edge 11 bent so that they are on their structural core 12.3 turned away side forms an interior angle. Due to the bending of the structural core plate 12 forms along the dividing line of the first cover plate 12.1 and the structural core 12.3 an open gap 32 out. This is through a corner cover 33 covered. The corner cover 33 is by two legs at an angle to each other 33.1 . 33.2 educated. The angle corresponds to the required angle of the edge 11 the clean cabin 10 , The thigh 33.1 . 33.2 are each on one side of the gap 32 with the outer second cover plate 12.1 the structural core plate 12 connected, in particular glued.

The structural core plates 12 has a high stability and bending stiffness with its low weight due to its structure. Therefore, a clean cabin 10 be built with a compared to conventional wall materials, such as solid aluminum or stainless steel, very low weight. Through the two cover plates 12.1 . 12.2 are structural core plates gas-tight. Also between the cover plates 12.1 . 12.2 can not gas inside the structural core 12.3 transverse to the surface normal of the structural core plate 11 flow, since the structural core elements in this direction with each other and to the cover plates 12.1 . 12.2 are tightly connected. In the present embodiment are structural core plates 12 with a honeycomb core as structural core 12.3 intended. Honeycomb cores lead to a high bending stiffness of the structural core plates 12 while transversely to the surface normal of the structural core plates 12 can be performed gas-tight.

As for the formation of the edge 11 only the outer second cover plate 12.2 and the structural core 12.3 were separated and the inner first cover plate 12.1 not according to the invention separated, but only bent, remains the structural core plate 12 in the area of the edge 11 gas-tight. This is a prerequisite for use as a side wall 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 a clean cabin 10 , As the structural core plate 12 is gas-tight across the surface normal, can across the gap 32 no gas introduced and across the structural core plate 12 to a possible, from the corner 11 spaced breakthrough of the inner first cover plate 12.1 and thus into the interior of the clean cabin 10 reach.

Through the corner cover 33 becomes the angle of the edge 11 given and stabilized. In addition, the corner cover seals 33 the area of the gap 32 from. It further prevents the inner first cover plate 12.1 accidentally from the outside through the gap 32 is damaged. Preferably, the corner cover 33 a rail bent along its longitudinal extension, in particular of aluminum.

In the present embodiment, the structural element plate 12 designed as aluminum honeycomb core plate. Here are the cover plates 12.1 . 12.2 and the structural core 12.3 made of aluminum. The structural core 12.3 has a honeycomb structure. This results in dense, mechanically very stable side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 receive. Aluminum behaves favorably over most of the clean cabin 10 required atmospheres inert.

5 shows an in 3 shown section V with a second corner 11.2 the clean cabin 10 in a perspective exterior view. Along the second corner 11.2 is the corner cover on the outer second cover plate 12.2 the structural core plate 12 glued. On the upper edge of the first horizontal side wall 30.8 are two profiled rails 62 attached. Here is the first horizontal side wall 30.8 in reception areas 62.2 the adjacent profile rails 62 introduced. On the openings of the receiving areas 62.2 opposite sides of the rails 62 are two-sided two support strips 62.1 in one piece to the receiving areas 62.2 formed. In the area of the second edge 11.2 the profiled rails come off 62 each other.

The profile rails 62 cover the open edges of the as structural core plate 12 executed side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 upwards. With mounted clean cabin 10 form the support strips 62.1 Contact surfaces to the overlying lid 40 , The contact surfaces can be tight, for example by gluing or by clamping, with the lid 40 get connected. For sealing seals can be arranged along the contact surfaces. Preferably, the contact areas between the rails 62 and the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 sealed. These can be sealing elements within the receiving areas 62.2 be provided or the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 are in the range of shooting areas 62.2 with the profile rail 62 bonded.

6 shows an in 3 shown section VI with a fifth corner 11.5 the clean cabin 10 in a perspective interior view. The cutout VI corresponds to the representation 5 but with a view of the interior angle of a corner 11.1 . 11.2 . 11.3 . 11.4 . 11.5 . 11.6 in the area of the upper end of a side wall 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 ,

The fifth vertical sidewall 30.5 is as a structural core plate 12 executed. The inner first cover plate 12.1 the structural core plate 12 is along the fifth corner 11.5 bent, so that forms an interior angle. Because the inner first cover plate 12.1 in the area of the fifth corner 11.5 Not is broken, the area of the fifth corner remains 11.5 gas-tight.

7 shows an in 3 shown section VII with a second corner 11.2 the clean cabin 10 in an external perspective view and in an exploded view.

The profile rails 62 are according to the angle of the second corner 11.2 Mitred cut. They indicate the receiving areas opened downwards 62.2 on, with which they are on upper edge of the shown in the section VII horizontal first side wall 30.8 be plugged.

The edge cover 33 is cut as an aluminum profile to the height of the corner area to be covered. Along the second corner 11.2 is the by separating the outer second cover plate 12.2 and the structural core 12.3 after bending the eighth side wall 30.8 formed gap 32 exposed.

Between the stacked first and second horizontal side walls 30.8 . 30.9 are connecting rails 60 intended. These are by means of the connection clips 61 and suitable fasteners, in particular screws, on the first and second horizontal sidewalls 30.8 . 30.9 assembled.

8th shows an in 3 shown section VIII with a second corner 11.2 the clean cabin 10 in a perspective external view in the region of two connecting rails 60 ,

The connecting rails 60 are between the first and the second horizontal sidewall 30.8 . 30.9 arranged. Here are the connecting rails 60 with landing sections 60.1 large area on the first and the second horizontal side wall 30.8 . 30.9 at. The connecting rails 60 are by means of the connection clamps 61 on the first and the second horizontal side wall 30.8 . 30.9 attached. The connection brackets 61 have holes 61.1 on. Through the holes 61.1 can fastening elements, in particular screws, are guided, with which the connecting brackets 61 on the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 , in the section shown VIII on the first and the second horizontal side wall 30.8 . 30.9 , can be attached.

The area between the feed sections 60.1 and the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 is preferably sealed. These sealing elements between the Anlegeabschnitten 60.1 and the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 be provided or the Anlegeabschnitte 60.1 can with the sidewalls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 be glued. The connecting rails 60 thus allow a gas-tight connection between adjacent side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 ,

At the second edge 11.2 are the connecting rails 60 Mitred cut.

9 shows two end-to-end side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 with an in 8th shown connecting rail 60 in a sectional view. Shown is an impact area between the first and the second horizontal side wall 30.8 . 30.9 ,

The connecting rail 60 is from a hollow profile 60.2 and the integrally formed thereon Anlegeeabschnitt 60.1 educated. Opposite to the landing section 60.1 is on the side of the second horizontal sidewall 30.9 a counter rail 60.3 to the hollow profile 60.2 formed. The counter rail 60.3 is according to the thickness of the second horizontal side wall 30.9 from the feed section 60.1 spaced. Between the feed section 60.1 , the opposite 60.3 and the hollow profile 60.2 Thus, a U-shaped area is formed, in which the second horizontal side wall 30.9 is plugged in. At the end are the first and the second horizontal side wall 30.8 . 30.9 on the hollow profile 60.2 at. The hollow profile 60.2 thus gives the distance between the first and the second horizontal side wall 30.8 . 30.9 in front. The connecting rail 60 lies with her landing section 60.1 from the outside at the first and the second horizontal side wall 30.8 . 30.9 at. The connection bracket 61 spans the landing section 60.1 transverse to its longitudinal extent. Side of the docking section 60.1 are the holes 61.1 in the connection bracket 61 brought in. Escaping to the holes 61.1 are screw receptacles 34 in the first and the second horizontal side wall 30.8 . 30.9 brought in. The connection bracket 61 is by screws, not shown, which through the holes 61.1 the connection bracket 61 in the screw receptacles 34 are guided, with the first and the second horizontal side wall 30.8 . 30.9 connected. This will be the connecting rail 60 held. At the same time prevents the connection bracket 61 in that the first and the second horizontal sidewall 30.8 . 30.9 remove each other. The area between the connecting rail is advantageous 60 and the first and second horizontal sidewalls 30.8 . 30.9 sealed, for example by sealing elements or by gluing. It is conceivable that the side wall 30.9 sealed glued into the U-shaped receptacle. Furthermore, it is conceivable and advantageous if the second side wall 30.8 can with the interposition of a running in the profile longitudinal direction seal at the Anlegeabschnitt 60.1 be supported. It is recommended that the seal on the hollow profile 60.2 facing away edge region of the Anlegeabschnittes 60.1 to arrange. It can then move laterally over the landing section when compressed. The projecting area can then likewise be used for sealing purposes. For example, this can be used to produce a sealing end to a component that adjoins the connecting rail at a right angle or at an angle.

The screw receptacles 34 pierce the first and second horizontal sidewalls 30.8 . 30.9 Completely. To here a gas entry into the clean cabin 10 To avoid sealing elements are provided which the screw receptacles 34 seal after the screws are mounted. In an alternative embodiment, the screw receptacles 34 only up to the inner first cover plate 12.1 the structural core plate 12 be guided. The inner first cover plate 12.1 This keeps it closed, so that no gas through the screw receptacles 34 penetrate or the clean cab 10 can leave. The structural core 12.3 prevents gas from starting from the screw receptacles 34 across the first or second horizontal sidewall 30.8 . 30.9 spreads.

The counter rail 63.3 simplifies the installation of the clean cabin 10 , By the opposite 63.3 can the connecting rail 60 first on one of the side walls to be connected 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 be plugged. This is the connecting rail 60 held. Then the adjoining side wall 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 with the connecting rail 60 get connected.

10 shows an in 3 shown section X with a vertically arranged connecting rail 60 in an exterior view.

The vertically arranged connecting rail 60 connects the illustrated first vertical side wall 30.1 with the in 3 shown three horizontal side walls 30.8 . 30.9 . 30.10 , Through the connecting rail 60 Thus, both horizontally and vertically arranged side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 be connected together gas-tight.

11 shows an in 3 shown section XI with a vertically arranged connecting rail 60 and an upper end of a first vertical side wall 30.1 in an exterior view.

The first vertical sidewall 30.1 is to the lid 40 the clean cabin 10 from the attached rail 62 covered. A guide element 63 is with a neck 63.2 in the open end of the hollow profile 60.2 the connecting rail 60 plugged in. At the neck 63.2 is a foot 63.1 formed. The foot 63.1 has the same profile as the support strip 62.1 the adjacent rail 62 on. The foot 63.1 and the pad strip 62.1 thus form a continuous surface. This is to the lid 40 aligned. The guide element 63 and the profile rail 62 thus allow a tight connection of the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 with the lid 40 along their upper edges and in the area of adjoining sidewalls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 ,

12 shows an in 3 shown section XII with a vertically arranged connecting rail 60 and a lower end of a first vertical sidewall 30.1 in an exterior view.

As in 11 for the upper termination of the first vertical sidewall 30.1 shown is also at the lower end of a rail 62 and in its extension a guide element 63 which with his neck 63.2 in the hollow chamber profile 60.2 the connecting rail 60 is plugged in, arranged. Again, form the foot 63.1 of the guide element 63 and the pad strip 62.1 the adjacent rail 62 a continuous area. This is to the ground 20 the clean cab aligned. The guide element 63 and the rails thus allow a tight connection of the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 with the ground 20 along their lower edges and in the area of adjoining sidewalls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 ,

13 shows an in 3 shown section XIII with a vertically arranged connecting rail 60 and a lower termination of the fifth and sixth vertical sidewalls 30.5 . 30.6 in an interior view.

The fifth and the sixth vertical sidewall 30.5 . 30.6 are with their lower edges in the receiving areas 62.2 the associated profile rails 62 plugged in. Between the fifth and the sixth vertical sidewall 30.5 . 30.6 is the connecting rail 60 arranged. The fifth vertical sidewall 30.5 is in through the counter rail 60.3 , which is arranged opposite to this, in 12 shown Anlegeabschnitt 60.1 and the hollow profile 60.2 inserted formed U-shaped area. Opposite to the against rail 60.3 is a mounting bracket 64 on the hollow profile 60.2 created. Preferably, the mounting bracket 64 with the hollow profile 60.2 connected. The mounting bracket 64 is with the sixth vertical sidewall 30.6 connected. Through the connecting rail 60 are the fifth and the sixth vertical sidewall 30.5 . 30.6 connected in a gastight manner.

The guide element 63 is with his neck 63.2 in the hollow profile 60.2 the connecting rail 60 at least partially inserted. This is the nozzle 63.2 in its outer contour to the contour of the cavity of the hollow profile 60.2 into the neck 63.2 inserted, adjusted. At the neck 63.2 a stop is provided which limits how far the nozzle is 63.2 in the hollow profile 60.2 can be inserted.

The support strips 62.1 the profile rail 62 and the foot 63.1 of the guide element 63 form a continuous, the ground 20 the clean cabin 10 facing surface, with which they are at the bottom 20 issue. The profile rail 62 and thus the fifth and the sixth vertical sidewall 30.5 . 30.6 are with retaining clips 65 which are on the ground 20 are attached and the support strip 62.1 the profile rail 62 clamp on a section connected to the ground.

14 shows an in 3 shown section XIV in the area of two adjoining floor slabs 22.1 . 22.2 in an exploded view. At the abutting edges of the two floor panels 22.1 . 22.2 are interlocking floor rails 23.1 . 23.2 appropriate. The floor rails 23.1 . 23.2 have recordings for fasteners with which the floor rails 23.1 . 23.2 can be connected.

In the present embodiment, the bottom rails 23.1 . 23.2 designed as separate components, which frontally to the bottom plates 22.1 . 22.2 attached, in particular glued, are. According to an alternative embodiment, the bottom rails 23.1 . 23.2 also in one piece to the floor panels 22.1 . 22.2 be formed.

At the edge of the floor plates 23.1 . 23.2 is positioning element 21 intended. The positioning element 21 opposite is a retaining clip 65 arranged. To be assembled with the positioning elements 21 and retaining clips 65 the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 with their rails 62 on the ground 20 positioned and fixed.

15 shows a carrier 80 the clean cabin 10 in a perspective view. The carrier 80 is as a double-T-straps with a first strap 81 a jetty 82 and a second belt 83 educated. Along the jetty 82 instructs the wearer 80 mounting holes 84 on. End is a chamfer 81.1 on the first belt 81 appropriate.

According to the invention, the carrier 80 made of structural core plates 12 built up. These are the first and the second belt 81 . 83 as well as the jetty 82 from appropriately cut structural core plates 12 produced. In the present embodiment, both the straps 81 . 83 as well as the bridge constructed of aluminum honeycomb core plates.

By making the carrier 80 made of structural core plates 12 can be compared to a conventional carrier 80 in massive construction significantly reduced in weight. Due to the high bending stiffness of the structural core plates used 12 and the construction in the form of a double-T-beam is a high-load carrier 80 obtained, which bends little under load.

In an alternative embodiment, not shown, of the structural core plates 12 produced carriers 80 as a simple T-beam or as a carrier 80 with a U-profile or an L-profile or other for carriers 80 be executed known profile.

16 shows the in 15 shown carrier 80 in a sectional view looking in the direction of the longitudinal extent of the carrier 80 ,

The first belt 81 and the second strap 83 are by means of connection angle 85 with the jetty 82 connected. The connection angle 85 extend over the length of the carrier 80 , They lie with a support surface on the bridge 82 and with a second bearing surface on the respective belt 81 . 83 at. There are every strap 81 . 83 two opposite each other at the footbridge 82 arranged connection angle 85 assigned. The connection angle 85 are stuck with the jetty 82 and the respective belt 81 . 83 connected. In particular, the connection angles 85 with the jetty 82 and / or with the belt 81 . 83 bonded.

Are carriers 80 provided with deviating from the double-T-shape carrier shapes, so are the connection angle 85 as shown for the double T-beam, along the butt joints between the assembled structural core plates 12 to arrange. The connection angle can be 85 be provided both as an internal angle and as an outer angle.

The mounting holes 84 are in the embodiment shown along the ridge 82 in the first strap 81 brought in.

Through the connection angle 85 can the straps 81 . 83 easy and fast with the jetty 82 get connected. The large-area bonding leads to the connection angle 85 with the straps 81 . 83 and the jetty 82 to a solid, resilient connection. Through the two sides of the bridge 82 attached connection angle 85 may be a tilting of the straps 81 . 83 opposite the jetty 82 with one-sided load of the carrier 80 safely avoided.

In the mounting holes 84 Fixing elements, in particular screws, can be specified. This allows more components of the clean cabin 10 , In the present embodiment, the cover plates 43 , with the carrier 80 get connected. The mounting holes 84 are, starting from the first cover plate 12.1 the first strap 81 used structural core plate 12 , only through the structural core 12.3 to the second cover plate 12.2 guided. The second cover plate 12.2 is not broken. This allows for a carrier 80 , on the first strap 81 from outside the clean cabin 10 inserted fasteners in the mounting holes 84 are introduced, no gas through the mounting holes 84 into the interior of the clean cabin 10 or from the clean cabin 10 get outside.

Are according to an embodiment, not shown, the mounting holes 84 due to a simpler production through both cover plates 12.1 . 12.2 guided, prevents their arrangement along the bridge 82 a gas exchange between the interior and the exterior of the clean gas cabin 10 , By on the side of the first belt 81 on both sides of the bridge 82 over the longitudinal extent of the carrier 80 glued connection angle 85 are the transitions from the jetty 82 to the first belt 81 sealed. So no gas from the mounting holes 84 along the contact surface between the first strap 81 and the jetty 82 in or out of the interior of the clean cabin 10 reach.

17 shows an in 3 shown section XVII in the area of the lid 40 the clean cabin 10 ,

The from structural core plates 12 formed cover plates 43 are each of a frame 43.1 framed. The frame 43.1 has a U-profile and is on the edges of the cover plates 43 attached, in particular glued. This creates a tight connection between the frame 43.1 and the respective cover plate 43 receive. The cover plates 43 are made of structural core plates 12 , in particular made of aluminum honeycomb core plates.

The cover plates 43 lie with their frames 43.1 on the first belt 81 one in the 15 and 16 shown carrier 80 on. It is the on the first belt 81 attached bevel 81 to the outer edge of the lid 40 aligned.

The carrier 80 is part of in 2 shown substructure 46 of the lid 40 , The cover plates 43 are by means of fasteners 44 on the carrier 80 established. The fasteners 44 has two laterally spaced clamping sections 44.1 on. Between the clamping sections 44.1 is a U-shaped bent attachment section 44.2 molded, in accordance with the in the first bridge 81 of the carrier 80 introduced mounting holes 84 not shown bores are introduced. The fastener 44 is about it with appropriate screws to the carrier 80 screwed. The clamping sections surround this 44.1 The frames 43.1 the adjacent cover plates 43 and clamp them to the carrier 80 firmly. The neighboring cover spouses 43 are through the attachment section 44.2 spaced and thus fixed in position.

At the outer edge of the lid 40 are how to 1 shown, edge fasteners 45 arranged. An edge fastener 45 is bent in an S-shape and has a clamping leg 45.1 and a mounting leg 45.2 on. In the attachment leg 45.2 holes are introduced. The clamping leg 45.1 surrounds the outer frame 43.1 the cover plate 43 , The attachment leg 45.2 is at the upper rails, not shown in the present presentation 62 the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 attached. The frame 43.1 the cover plate 43 is so between the clamping leg 45.1 and the support strip 62.1 the respective rail 62 trapped. Thus, the lid is safe on the side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 held. Preferably, the support area of the frame 43.1 on the carrier 80 and the profile rail 62 sealed.

18 shows an in 3 shown section XVIII in the area of an attachment of the support structure 70 the clean cabin 10 , The support structure 70 serves the edition of in 2 shown gas processing unit 55 and the filter provided therein 56 ,

Shown is the attachment of the support structure 70 in the area of the fifth corner 11.5 the clean cabin 10 , At the fifth vertical side wall 30.5 is already in 3 shown, U-shaped mounting rail 71 appropriate. At the mounting rail 71 is a carrier pad 72 attached. The carrier pad 72 forms a half-shell into which a carrier 80 the support structure 70 is inserted. In the area of the carrier pad 72 is an upper one Legs of the mounting rail 71 left out, leaving the carrier 80 in the carrier pad 72 can be inserted. The recess is with a cover 73 covered. The carrier 80 is thus safe on the fifth vertical side wall 30.5 established.

At the positions of the outer ends of the carrier 80 the in 3 shown carrying structure 70 are on the sidewalls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 carrier supports 72 appropriate. When installing the clean cabin 10 so can the pre-assembled support structure 70 introduced from above into the interior of the clean cabin and on the carrier pads 72 be filed. Preferably, the carriers 80 the support structure 70 with the carrier pads 72 connected, in particular screwed.

Unlike in the 15 and 16 shown embodiment of the carrier 80 are the mounting holes 84 the carrier 80 the support structure 70 side of the bridge 82 of the carrier 80 attached as a through hole. Fixing screws of the filters 56 so can through the mounting holes 84 guided and bolted from below with a nut. Because the support structure 70 in the interior of the clean cabin 10 is arranged here no additional sealing measures are required.

The in the 1 to 18 shown, mainly from structural core plates 12 manufactured clean cabin 10 has a very low weight compared to known clean cabins. This can the clean cab 10 easier to transport and set up. The demands on the floor load at their place of installation can be reduced. Due to the structure shown is the interior of the clean cab 10 sealed against the environment. Thus, the required atmosphere in the interior of the clean cabin 10 be set and respected. Critical processes and work steps can thus be carried out in a suitable atmosphere. A built according to the concept shown clean cabin 10 can be easily adapted in size to the respective requirements. This can be the size and number of provided floor panels 22.1 . 22.2 . 22.3 , Side walls 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 and cover plates 43 as well as the required carrying structures 70 be designed accordingly. The floor plan of the clean cabin 10 can be adapted from the hexagonal shape shown to any other polygonal shapes.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 624855 [0006]

Cited non-patent literature

• Standard EN 10025 [0005]
• "Cleanroom technology", 3rd updated u. ext. Ed., Springer, pp. 202-207 [0010]

Claims (12)

Carrier ( 80 ), in particular profile carrier, with at least two profile elements connected to one another at an angle, in particular at least one belt ( 81 . 83 ) and a jetty ( 82 ), characterized in that at least one of the profile elements of a structural core plate ( 12 ), in particular from a honeycomb core plate, each with two cover plates ( 12.1 . 12.2 ) and a structural core ( 12.3 ), in particular honeycomb core, is formed. Carrier ( 80 ) according to claim 1, characterized in that the at least one profile element is formed from an aluminum honeycomb core plate. Carrier ( 80 ) according to claim 1 or 2, characterized in that at least two profile elements of the carrier ( 80 ) via at least one connecting angle ( 85 ) and / or that a side leg of the connection angle ( 85 ) with a profile element and a second side leg of the connection angle ( 85 ) with another profile element of the carrier ( 80 ) connected is. Carrier ( 80 ) according to claim 3, characterized in that the at least one connecting angle ( 85 ) is arranged along an inner angle or outer angle formed between the profile elements. Carrier ( 80 ) according to claim 3 or 4, characterized in that the at least one connecting angle ( 85 ) is glued to the profile elements to be joined. Carrier ( 80 ) according to one of claims 1 to 5, characterized in that the carrier ( 80 ) is designed as a T-carrier or as a double-T carrier or that the carrier ( 80 ) has a U-profile or a C-profile or a Z-profile or an L-profile or that the carrier is designed as a square tube. Carrier ( 80 ) according to one of claims 1 to 6, characterized in that at least two profile elements of the carrier ( 80 ) from a common structural core plate ( 12 ) are formed, that along a joint edge between the profile elements, the one cover plate ( 12.1 . 12.2 ) of the structural core plate ( 12 ) and the other cover plate ( 12.1 . 12.2 ) and the structural core ( 12.3 ) are separated, that the gap formed along the abutting edge in the split cover plate ( 12.1 . 12.2 ) and in the structural core ( 12.3 ) of a connection angle ( 85 ) and that the connection angle ( 85 ) with its side legs each with the severed cover plate ( 12.1 . 12.2 ) is connected on both sides of the gap. Clean cabin ( 10 ) with a sealed to the environment, of side walls ( 30 . 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 ) surrounded interior, characterized in that at least a part of the side walls ( 30 . 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 ) of the clean cabin ( 10 ) from one or more structural core plates ( 12 ), in particular one or more honeycomb core plates, each with two cover plates ( 12.1 . 12.2 ) and a structural core ( 12.3 ), in particular honeycomb core, are formed such that the construction of the clean cabin ( 10 ) intended carriers ( 80 ) Profile carrier with at least two profile elements connected to one another at an angle, in particular at least one belt ( 81 . 83 ) and a jetty ( 82 ), and that at least one of the profile elements of a structural core plate ( 12 ), in particular from a honeycomb core plate, each with two cover plates ( 12.1 . 12.2 ) and a structural core ( 12.3 ), in particular honeycomb core, is formed. Clean cabin ( 10 ) according to claim 8, comprising at least one carrier ( 80 ) according to one of claims 2 to 6. Clean cabin ( 10 ) according to claim 8 or 9, characterized in that a floor ( 20 ) of the clean cabin ( 10 ) of one or more structural core plates ( 12 ), in particular as honeycomb core panels, executed floor panels ( 22 . 22.1 . 22.2 . 22.3 ) and / or that the clean cab ( 10 ) upwards through one of at least one cover plate ( 43 ) formed lid ( 40 ) and that the cover plate ( 43 ) from a structural core plate ( 12 ), in particular honeycomb core plates, is formed. Clean cabin ( 10 ) according to one of claims 8 to 10, characterized in that a plurality of carriers ( 80 ) a support structure ( 70 ) is formed and that the support structure ( 70 ) directly or indirectly on the side walls ( 30 . 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 ) is attached. Clean cabin ( 10 ) according to claim 10 or 11, characterized in that a plurality of carriers ( 80 ) a substructure ( 80 ) is formed on the substructure ( 80 ) the at least one cover plate ( 43 ), and that the substructure ( 80 ) directly or indirectly on the side walls ( 30 . 30.1 . 30.2 . 30.3 . 30.4 . 30.5 . 30.6 . 30.7 . 30.8 . 30.9 . 30.10 ) is attached.

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