WO2023169703A1 - Method, device and system for creating a controlled environment in a work area on a surface - Google Patents

Abstract

The invention relates to a fluid conduit and a method for creating a controlled environment in a work area on a surface, the method comprising the following steps: arranging a fluid conduit on the surface adjacent to the work area, wherein the fluid conduit has a porous exit region for a preferably gaseous fluid, which exit region defines a stream running along the surface towards the work area, and the fluid conduit is pleated.

Description

Method, device and system for creating a controlled environment in a surface work area

The invention relates to a method, a device and a system for producing a controlled environment in a work area located on a surface, in particular a work area suitable for clean rooms.

Such controlled environments are required, for example, in work areas in which work is carried out under clean room conditions. Such work areas are, for example, in clean rooms for the production of sensitive technical devices or in medical operating areas or -halls to be found.

In these work areas, the entry of external influences such as particles, foreign bodies or external flows from the surroundings of the work area should be prevented or (greatly) reduced. Such external influences can also come from people working in or around the work area and/or be transported towards the work area.

Devices, systems and methods for producing controlled environments in such clean rooms or isolated work areas are known. The present invention is based on the object of improving and/or simplifying such devices and methods.

The solution to this problem in the method of the type mentioned at the beginning is in particular that the method comprises: arranging a fluid line on the surface adjacent to the working area, the fluid line having a porous passage area, in particular outlet area, for a preferably gaseous fluid the one A stream running along the surface to the working area is formed, characterized in that the fluid line is pleated.

The passage area can, for example, be designed as an outlet area in that an excess pressure is present inside the fluid line through which the fluid exits. This makes it possible to create a controlled environment in which the entry of undesirable substances can be reduced or even prevented.

The passage area can alternatively be designed as an entry area in that a negative pressure is present inside the fluid line through which fluid enters. This can be used advantageously to extract unwanted or even dangerous substances, such as carcinogenic substances, from the work area. A controlled environment can therefore be implemented in which the escape of substances from the work area into an environment can be reduced or even completely prevented. It has been found that by pleating and/or by coating the hose, in particular additionally, sufficient stability of the fluid line can be achieved in order to withstand the necessary negative pressure.

For example, the fluid line is designed as a pleated hose. A pleated fluid line can be designed like a pleat. For example, the pleated fluid line can be wave-shaped or Be designed in the shape of a corrugated tube or have tapered edges. In other words: The pleated fluid line can have alternating elevations and depressions.

Pleating the fluid line makes it special flexible structure of the fluid line achieved. This makes it possible to achieve an optimal arrangement of the fluid line on the surface, for example on an uneven surface, as usually occurs on the human body.

In addition, the pleated fluid line can change its shape without additional support elements or the like. ä . retained. In particular, the pleated fluid line is resilient, i.e. H . it can return to its original shape following an external force. This simplifies the production of the fluid line and improves its arrangement and thus the method for producing the controlled environment.

Through the pleating, folds can be formed which can act as a support element, for example to prevent the fluid line from collapsing in the event of a pressure drop or low pressures.

In addition, the porous passage area, in particular the exit area, has the advantage that the exiting fluid does not generate any, very weak or only small turbulences outside the fluid line when exiting, but rather exits evenly or uniformly. In other words: A laminar or sheet-like stream is formed through the porous passage area, in particular the exit area. This means that the electricity generated does not suck in any or a reduced amount of particles, foreign bodies or foreign flows from the surroundings of the work area. The entry of these external influences into the work area is prevented (to a greater extent). In this way, a controlled environment can be created in a simple and effective manner, particularly in smaller work areas. A porous passage area, in particular exit area, is characterized, for example, in that a respective size or a respective diameter of several openings of the passage area, in particular exit area, is greater than or equal to a distance to a respective adjacent opening of the passage area, in particular exit area . Likewise, a porous passage area, in particular exit area, can be characterized, for example, in that the summed (total) opening area of several openings of the passage area, in particular exit area, is greater than or equal to half the total area of the passage area, in particular exit area, in in which the several openings are arranged.

In one embodiment it is provided that circumferential folds, in particular an arrangement of several circumferential folds, are formed on the fluid line by the pleating. In other words: The pleat is formed transversely to a longitudinal direction of the fluid line. A desired flexibility and/or stability of the fluid line can be set by the number and/or size of the folds.

The described orientation of the folds has, on the one hand, the advantage that the fluid line can adapt flexibly to uneven floors in the direction of the fluid line, and, on the other hand, the advantage that an opening cross section of the fluid line can be kept open by the folds acting as support elements, even if a Pressure inside the fluid line drops or is selected to be only slightly (e.g. a few Pa) above an ambient pressure.

The described orientation of the folds can cause a

Sequence of mountains and valleys or of maximums and minimums Opening cross sections in the direction of the fluid line.

In one embodiment it is provided that the passage area, in particular the exit area, is designed like a filter, textile-like and/or fleece-like. In this way, a particularly uniform entry and/or exit of the flow from and/or into the passage area, in particular the exit area, can be achieved. In particular, this can be used to provide a flow that is not nozzle-like but rather flat or laminar and thus produces no or at least a reduced backflow into the work area and/or which predominantly or completely captures the work area for suction.

In one embodiment it is provided that the exit area comprises knitted textile or (other) textile knitwear. The meshes formed offer the advantage that if there is damage at one point on the fluid line, the entire hose is prevented from being separated. In addition, it has been found that a knitted fabric or a textile knitted fabric forms an exit area that has particularly suitable fine porous openings. The fluid line designed in this way also has no seam that may be disruptive, particularly disruptive to a uniform flow. Such a fluid line, for example, has a mass of approximately 10 g/m. Furthermore, the fluid line can be designed to be emission-free and/or lint-free. Emission-free fluid lines are particularly suitable for medical applications and are made, for example, from filament material with medical approval. In one embodiment it is provided that the pleated fluid line comprises a limiting means through which away flow, which is oriented away from the working area, is prevented.

The flow directed away flows out, for example, on the side of the fluid line opposite the working area. Likewise, the flow directed away can lie outside an angular range of the fluid line, which includes the working area, whereby the passage area, in particular exit area, can be limited to a (center or center) angular range that is less than 360 °, in particular less than or equal to 270 ° or is less than or equal to 90°.

The away flow is prevented, for example, by a part of the fluid line, in particular a section along an outer circumference of the fluid line, being impermeable to the fluid flow. For example, the passage area, in particular the exit area, is only attached along part of the outer circumference of the fluid line or is covered on part of the outer circumference. This prevents a negative pressure caused by the flow directed away from being generated near the work area, which can suck in external contamination from the environment.

In one embodiment it is provided that the limiting means comprises a coating of the passage area, in particular the exit area. This makes it possible to focus in a particularly simple and effective way

Current can be achieved.

In one embodiment it is provided that the pleated

Conducting fluid through a surface fastener is attached, in particular wherein the fastening means comprise adhesive points on one or more elevations of the pleated fluid line. The fastening means can also consist of an adhesive, Velcro, magnet or weight element. The fluid line can be detachably attachable to the fastening means. Additionally or alternatively, the fastening means can be detachably attachable to the surface.

In this way, the fluid line can be arranged on the surface safely and in a simple and effective manner. The elevations can, for example, be the peaks or mountains of the pleated or corrugated structure of the fluid line. This means that the fastening means can be used ef fi ciently.

In one embodiment it is provided that the fluid line is arranged along a marking of the fluid line on the surface, in particular wherein the marking is arranged on a side of the fluid line opposite the fastening means.

For example, the fluid line (top side) has an identification thread or a color marking. This allows the fluid line to be correctly attached to the surface, in particular with correct orientation and without undesirable twisting or twisting of the fluid line. Furthermore, the marking allows a precise arrangement of the fastening means or the adhesive spots on the surface.

In one embodiment it is provided that the method further comprises: cooling the fluid to form a cooled stream. This allows a higher density of the current compared to the ambient air and thus an improved

Adhesion of the current to the work area can be achieved. As a further possibly independent aspect, the solution to the task mentioned at the beginning in the device of the type mentioned at the beginning consists in particular in that a fluid line with a porous passage area, in particular outlet area, for a preferably gaseous fluid, in particular for the implementation of one of the above-mentioned Method is provided, wherein the fluid line is pleated.

In one embodiment it is provided that circumferential folds, in particular an arrangement of several circumferential folds, are formed on the fluid line by the pleating.

In one embodiment it is provided that the passage area, in particular the exit area, is designed like a filter, textile-like and/or fleece-like.

In one embodiment it is provided that the passage area, in particular exit area, comprises knitted textile, textile knitwear or textile fabric.

In one embodiment it is provided that the pleated fluid line comprises a limiting means for preventing away flow that is oriented away from the working area.

In one embodiment it is provided that the limiting means comprises a coating of the passage area, in particular the exit area.

In one embodiment it is provided that the fluid line comprises a fastening means for fastening the fluid line to a surface, in particular wherein the Fastening means includes adhesive points on one or more elevations of the pleated fluid line.

In one embodiment it is provided that the fluid line comprises a marking for arranging the fluid line on the surface, in particular wherein the marking is arranged on a side of the fluid line opposite the fastening means.

As a further possibly independent aspect, the solution to the task mentioned at the outset in the system of the type mentioned at the outset alternatively consists in particular in that a system for producing a controlled environment is provided in a work area located on a surface, the system comprising: one of the above described fluid lines; and a cooling device for cooling the fluid, in particular for forming a cooled stream.

It shows :

Fig. 1 a fluid line in a three-dimensional representation for producing a controlled environment in a first work area located on a surface,

Fig. 2 the fluid line in a three-dimensional representation for creating a controlled environment in a second work area located on the surface,

Fig. 3 a first three-dimensional sectional view of the fluid line,

Fig. 4A-C three two-dimensional sectional views of fluid lines with differently designed cross sections, Fig. 5 a second three-dimensional sectional view of the fluid line,

Fig. 6A-B a three-dimensional view of the fluid line according to a further embodiment and a two-dimensional sectional view of the same,

Fig. 7 a system for creating a controlled environment in a surface work area.

Figure 1 shows a surface 1. A work area 2 is arranged on the surface 1 . In other words: The work area 2 is located in or on the surface 1. The work area 2 represents, for example, a work area 2 for assembly work on sensitive technical devices, such as optical instruments or measuring devices. The work area 2 can also represent an operating area, for example for eye operations, minimally invasive or other operations. The surface 1 can therefore represent human or animal tissue, for example skin.

A user 3 of the work area 2 faces the work area 2. The user 3 positions himself above the work area 2. The user 3 is positioned between the work area 2 and a ventilation means 9 or a ventilation system. The ventilation means can provide already filtered air or clean room air in the vicinity of the work area 2.

Under clean room conditions, all or as many external influences as possible should be kept away from the work area. Such external influences are, for example, particles 4, Foreign flows 5 or other foreign bodies or - fluid. The external flows 5 include, for example, clean room air, which in the example shown flows from top to bottom, starting from the ventilation means 9. The particles 4 can come, for example, from the user 3 himself or from the environment of the work area 2. The particles 4 can be, for example, viruses, bacteria or lint.

To keep external influences away from the work area 2, a fluid line 6 is attached to the surface 1 adjacent to the work area 2.

The fluid line 6 comprises a porous passage area, described by way of example as the outlet area 7. The exit area 7 can also be used as an entry area for a suction.

The exit area 7 is, for example, fleece-like, textile-like, filter-like or sieve-like. For example, the exit area 7 is a filter fabric. In a preferred exemplary embodiment, the exit region 7 comprises knitted textile or textile knitwear.

A stream 8 or fluid stream emerges from the outlet region 7. The stream 8 is, for example, gaseous. At least part of the stream 8 runs along the surface 1 in the direction of the work area 2, in particular at least partially across the work area 2. This part of the stream 8 can adhere to the surface 1. The fluid flow 8 fills the circular or. ring-shaped fluid line 6 enclosed area with particle-free air. This protects the work area 2 from contamination. The particle-free air is supplied to the fluid line 6 via a

Fluid supply 14 supplied. The fluid line 6 is pleated or Pleated-like design. In the example shown, several circumferential folds are formed around the fluid line. The pleated fluid line 6 can be wave-shaped or be designed in the shape of a corrugated tube. Due to the pleating, the fluid line 6 has elevations and depressions that are arranged alternately. The pleating of the fluid line 6 allows a flexible arrangement of the fluid line 6 on the surface 1 and gives the fluid line 6 stability. The fluid line can be arranged in this way, for example, with a bending radius of a few millimeters, for example 20 mm, in particular without a bend.

Through the exit area 7, part of the emerging stream 8 can be inclined or perpendicular to the surface 1 or Lead diagonally or vertically away from surface 1. This creates an overall flow that flows from the surface 1 or is directed away from the work area 2. In this way, the particles 4 and the external flow 5 are kept away from the work area 2. The total flow can also be referred to as the displacement flow.

Figure 2 shows an embodiment of the fluid line 6, which is similar or the same as the fluid line 6 shown in Figure 1. Same or similar ä . Features are given the same reference symbols. There is a recess 13 within the work area 2. The depression 13 can be, for example, a hole or incision or a wound in the skin of a patient. A negative pressure relative to the ambient air can arise within the depression 13 . For example, the depression 13 represents a section of the abdominal wall of a patient, with a lower air pressure below the abdominal wall than in the surroundings of the work area. In this way, air flows from outside into the recess 13. This can result in an increased risk of contamination. Through the over the The particle-free stream 8 provided by the fluid line 6 reduces this risk of contamination.

Figure 3 shows a sectional view of the fluid line 6 shown in Figure 2. Same or similar ä . Features are given the same reference symbols.

It can be seen particularly well in Figure 3 that a supply line 11 for the fluid supply 14, which is T-shaped in the example shown, has perforations 27. This allows a uniform or Area-wide stream 8 can be provided within the working area 2 enclosed by the fluid line 6. The perforations 27 can be slot-shaped, as in the example shown. Alternatively, the perforations 27 can be designed similarly to or the same as the outlet area 7, in particular providing a porous area of the supply line 11.

Figures 4A, 4B and 4C each show cross sections of an embodiment of the fluid line 6, which is similar or the same as the fluid line 6 shown in Figures 1 or 2. Same or similar ä . Features are given the same reference symbols. As shown in FIGS. 4A, 4B and 4G, the fluid line 6 can have a round or circular or a polygonal cross-section, for example a rectangular, square or 6-edged cross-section. The fluid lines can have a diameter of 10-30 mm, for example.

As can be seen in FIGS. 4A, 4B and 4G, the fluid line 6 also includes a fastening means 10. The fastening means 10 is attached to the fluid line 6. The fastening means 10 includes, for example, adhesive points. The fastening means 10 can in particular be attached to one or more elevations of the pleated fluid line 6. The fluid line 6 can be fastened, in particular releasably, to the surface 1 via the fastening means 10. The adhesive points can be skin-neutral and/or made of adhesive material with medical approval.

As can be seen in FIGS. 4A, 4B and 4C, the fluid line 6 also includes a limiting means 15. The shape of the limiting means can correspond to an external shape of at least part of the fluid line 6 or reshape these. The limiting means 15 can, for example, be a coating on the fluid line 6 or of the exit area 7 include.

The limiting means 15 can prevent flow directed away from the working area 2. In this way, the fluid flow 8 can be concentrated or concentrated on the working area 2. be focused.

Figure 5 shows a further sectional view of an embodiment of the fluid line 6, which is similar or the same as the fluid lines 6 shown in Figures 1-4. Same or similar ä . Features are given the same reference symbols.

As can be clearly seen, the fluid line 6 includes a marking 12. The marking 12 is attached to a side of the fluid line 6 opposite the fastening means 10 . Alternatively or additionally, the marking 12 is at a defined, in particular constant, distance from the fastening means 15 or attached to the fasteners 15. The marking 12 serves to correctly attach the fluid line 6 to the surface 1. In particular, a twist or twist of the fluid line 6 can be made visible by the marking 12. In addition, the marking 12 can be used to ensure that when the fluid line 8 is attached, this may be caused by the fluid line 6 concealed fastening means 10 is correctly placed on the surface 1 or is brought into contact with the surface 1.

Figures 6A and 6B show a further embodiment of a fluid line 6, which is similar or the same as the fluid lines 6 shown in Figures 1-5. Same or similar ä . Features are given the same reference symbols.

In the example shown, the fluid line 6 is attached to a patient's hand. As shown in FIG. 6B, the stream 8 emerging from the fluid line 6 comprises a Coanda flow 16. In other words: At least part of the stream 8 has properties of a Coanda flow. The Coanda flow 16 adheres to the surface 1 and protects the work area 2 particularly well against contamination. By pleating the fluid line 6, the Coanda flow 16 can form directly on the surface 1, in particular already below the fluid line 6.

Figure 7 shows a system for creating a controlled environment in a work area located on a surface. The system comprises at least one fluid line 6, in the example shown, differently shaped fluid lines 6, to which a fluid can be supplied together or separately through the fluid supply 14.

The system further includes a cooling device 17. The cooling device 17 can be a heat exchanger. The cooling device 17 is designed to cool fluid before supplying it to the fluid line 6, whereby a cooled fluid stream 8 can be provided. A cooled fluid stream 8 can better adhere to the surface 1 within the work area 2 and thus better protect the work area 2 from contamination. The system further includes a pre-filter 18 from which outside air passes into a fan 19. The fan 19 is driven by a controllable motor 20. The regulation takes place via a controller 21. The air from the fan 19 reaches a first measuring device 23 via a Hepa filter 22. The first measuring device 23 can in particular be designed to determine the air pressure of the supplied air flow. The air pressure or the dynamic pressure of the fluid can be measured. The control 21 or A control cabinet comprising the control 21 can be supplied with outside air for cooling via a fan 24 and the pre-filter 18.

Reference symbol list

1 surface

2 work area

3 users

4 particles

5 external flow

6 fluid line

7 exit area

8 fluid flow

9 ventilation means

10 fasteners

11 supply line

12 mark

13 deepening

14 fluid supply

15 limiting means

16 Coanda Current

17 cooling device

18 pre-filters

19 fan

20 engine

21 Control

22 Hepa filters

23 First measuring device

24 fans

25 Derivation

26 Second measuring device

27 perforations

28 A system comprising the fluid line

Claims

Expectations

1. A method for producing a controlled environment in a work area (2) located on a surface (1), the method comprising:

Arranging a fluid line (6) on the surface (1) adjacent to the working area (2), the fluid line (6) having a porous passage area, in particular outlet area (7), for a preferably gaseous fluid, through which a fluid flows along the surface ( 1) a stream (8) running to the working area (2) is formed, characterized in that the fluid line (6) is pleated.

2. The method according to claim 1, wherein circumferential folds, in particular an arrangement of several circumferential folds, are formed on the fluid line (6) by the pleating and/or wherein the passage area, in particular outlet area (7), is filter-like, textile-like and/or fleece-like is trained.

3. The method according to any one of the preceding claims, wherein the passage area, in particular exit area (7), comprises knitted textile or textile knitwear and / or wherein the pleated fluid line (6) comprises a limiting means (15) through which the away flow from is oriented away from the work area (2).

4. The method according to any one of the preceding claims, wherein the limiting means (15) comprises a coating of the passage area, in particular exit area (7), and / or wherein the pleated fluid line (6) is attached to the surface (1) by a fastening means (10). is, in particular wherein the fastening means

(10) Include adhesive points on one or more elevations of the pleated fluid line (6). Method according to one of the preceding claims, wherein the fluid line (6) is arranged along a marking (12) of the fluid line (6) on the surface (1), in particular wherein the marking (12) is on a side of the fastening means (10) opposite Fluid line (6) is arranged. Method according to one of the preceding claims, further comprising: cooling the fluid to form a cooled stream (8). Fluid line (6) with a porous outlet region (7) for a preferably gaseous fluid, in particular for carrying out a method according to one of the preceding claims, characterized in that the fluid line

(6) is pleated. Fluid line (6) according to claim 7, wherein circumferential folds, in particular an arrangement of several circumferential folds, are formed on the fluid line (6) by the pleating. Fluid line according to one of claims 7-8, wherein the passage area, in particular outlet area (7), is designed like a filter, textile-like and / or fleece-like. Fluid line (6) according to one of claims 7-9, wherein the passage area, in particular outlet area (7), comprises knitted textile, textile knitwear or textile fabric. Fluid line (6) according to any one of claims 7-10, wherein the pleated fluid line (6) comprises a restriction means for preventing away flow oriented away from the working area (2). Fluid line (6) according to claim 11, wherein the limiting means comprises a coating (15) of the outlet region (7). Fluid line (6) according to one of claims 7-12, wherein the fluid line (6) comprises a fastening means (10) for fastening the fluid line (6) to a surface (1), in particular wherein the fastening means have adhesive dots on one or more elevations of the pleated Fluid line (6) includes. Fluid line (6) according to one of claims 7-13, wherein the

Fluid line (6) comprises a marking (12) for arranging the fluid line (6) on the surface (1), in particular wherein the marking (12) is arranged on a side of the fluid line (6) opposite the fastening means (10). System for creating a controlled environment in a work area (2) located on a surface (1), the system comprising: a fluid line (6) according to one of claims 7-14; and a cooling device (17) for cooling the fluid, in particular for forming a cooled stream (8).