Classifications

• • A—HUMAN NECESSITIES
  • A62—LIFE-SAVING; FIRE-FIGHTING
  • A62B—DEVICES, APPARATUS OR METHODS FOR LIFE-SAVING
  • A62B17/00—Protective clothing affording protection against heat or harmful chemical agents or for use at high altitudes
• • A—HUMAN NECESSITIES
  • A41—WEARING APPAREL
  • A41D—OUTERWEAR; PROTECTIVE GARMENTS; ACCESSORIES
  • A41D13/00—Professional, industrial or sporting protective garments, e.g. surgeons' gowns or garments protecting against blows or punches
  • A41D13/002—Professional, industrial or sporting protective garments, e.g. surgeons' gowns or garments protecting against blows or punches with controlled internal environment
  • A41D13/005—Professional, industrial or sporting protective garments, e.g. surgeons' gowns or garments protecting against blows or punches with controlled internal environment with controlled temperature
  • A41D13/0051—Heated garments
• • A—HUMAN NECESSITIES
  • A62—LIFE-SAVING; FIRE-FIGHTING
  • A62B—DEVICES, APPARATUS OR METHODS FOR LIFE-SAVING
  • A62B17/00—Protective clothing affording protection against heat or harmful chemical agents or for use at high altitudes
  • A62B17/005—Active or passive body temperature control
• • H—ELECTRICITY
  • H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
  • H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
  • H05B3/00—Ohmic-resistance heating
  • H05B3/20—Heating elements having extended surface area substantially in a two-dimensional plane, e.g. plate-heater
  • H05B3/34—Heating elements having extended surface area substantially in a two-dimensional plane, e.g. plate-heater flexible, e.g. heating nets or webs
• • H—ELECTRICITY
  • H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
  • H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
  • H05B3/00—Ohmic-resistance heating
  • H05B3/84—Heating arrangements specially adapted for transparent or reflecting areas, e.g. for demisting or de-icing windows, mirrors or vehicle windshields
• • A—HUMAN NECESSITIES
  • A41—WEARING APPAREL
  • A41D—OUTERWEAR; PROTECTIVE GARMENTS; ACCESSORIES
  • A41D19/00—Gloves
  • A41D19/015—Protective gloves
  • A41D19/01529—Protective gloves with thermal or fire protection
  • A41D19/01535—Heated gloves
• • H—ELECTRICITY
  • H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
  • H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
  • H05B2203/00—Aspects relating to Ohmic resistive heating covered by group H05B3/00
  • H05B2203/022—Heaters specially adapted for heating gaseous material
• • H—ELECTRICITY
  • H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
  • H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
  • H05B2203/00—Aspects relating to Ohmic resistive heating covered by group H05B3/00
  • H05B2203/033—Heater including particular mechanical reinforcing means
• • H—ELECTRICITY
  • H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
  • H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
  • H05B2203/00—Aspects relating to Ohmic resistive heating covered by group H05B3/00
  • H05B2203/036—Heaters specially adapted for garment heating

Definitions

• the invention relates to a protective suit for use by an operator in a cold room, in particular in a refrigeration system for cryopreserving biological samples.
• the He ⁇ invention also relates to a glove for use with the suit or in a cooling system for the cryopreservation of biological samples.
• Applications of the invention are in the operation of refrigeration systems for long-term storage of samples in the cooled state, especially in the cryopreservation of biological samples, given. It is known biological samples for preservation purposes in the frozen state in a refrigeration system, for. B. in a cryobank to store (cryopreservation). Cryobanks are typically operated at temperatures below -80 ° C, in particular at a temperature below the recrystallization temperature of water ice (-138 ° C).
• cryogenic tanks mostly double-walled Dewar vessels.
• the cryogenic tanks stand in rooms at normal temperature (room temperature), in which operators can be without special protective measures.
• Conventional cryobanks with individual cryotanks have disadvantages when it comes to cryopreserving large quantities of samples, such as ten thousand to one million or more samples.
• the cooling system comprises a cooling space and a cooling device, which is provided for cooling de% refrigerator with liquid nitrogen.
• the object of the invention is to provide improved protection of an operator in a cooling plant for the cryopreservation of biological samples, said drawbacks and limitations of conventional Be ⁇ protection measures to be overcome.
• This object is achieved by a protective suit having the features of claim 1.
• Advantageous embodiments and applications of the invention will become apparent from the dependent claims. According to the invention, the above object is achieved by the general technical teaching, a protective suit, in particular for an operator in a cold room with a temperature below -100 ° C, especially below -150 ° C, z. B. -190 ° C or below, comprising a body suit for receiving the operator and a heater for heating the body suit.
• the protective suit is adapted for use in a cold room cooled in particular with liquid nitrogen or liquid nitrogen vapor.
• the body suit is made of a thermally insulating jacket material (shell material).
• the jacket material forms a gas-tight envelope for the operator.
• the heater is connected to the body suit and tuned with the thermal conductivity of the jacket material so that inside the body suit a physio- logically acceptable temperature (temperature above -30 ° C, especially above -10 ° C, eg 0 ° C or above) is provided.
• the heater or parts of this are connected to the jacket material of the body suit, so that it is directly tempered by the heater.
• a protective suit can be provided which provides reliable protection for a person in the cold room cooled even with extremely low temperatures in liquid nitrogen Protective suit offers.
• the protective suit provides complete and safe thermal insulation of the entire body of the operator. At the same time, the heat output from the operator in the cold room is minimized. The operator may wear normal clothing, laboratory clothing or warm (lined) textile clothing in the suit.
• the heater performs a dual function by firstly providing a sufficient temperature inside the body suit and secondly, the jacket material and / or other parts of the body suit such. B. joint areas can be heated so that at the low temperature in the refrigerator sufficient flexibility is given to ensure the mobility of the operator in the refrigerator.
• the protective suit according to the invention offers protection of the entire body of the operator, in particular the legs, feet, arms and hands against cooling, even in the case of direct contact of the outside of the protective suit with liquid nitrogen.
• the operator can move freely in the protective suit in the cold room and use the protective suit autonomously.
• the use in the cold room is for a period of at least 10 Minutes, especially at least 30 minutes, such as 60 minutes or longer possible.
• the heating device comprises an electrical resistance heater.
• the resistance heating can advantageously be easily embedded in the jacket material of the body suit or positioned on its inner surface.
• the resistance heating also has advantages in terms of power supply via an electrical line connection to an internal and / or external power source and a short response time when changing the temperature in the body suit.
• Trains t ⁇ comprises the electrical resistance heating Schuschich ⁇ th, which are positioned distributed in the body suit.
• Heating layers comprise layered resistance materials, such as metallic alloys, tungsten, plastic films vapor-coated with heating resistors, or indium tin oxide layers. Heating layers have the advantage of minimizing the wearing comfort for the operator.
• the heating device may comprise a heating medium circuit which extends into the body suit.
• the heating medium circuit is embedded in the sheath material of the body suit or positioned on the inner surface and with a ⁇ ternal and / or external heating medium source for a gaseous or liquid heating means, such as air or silicone oil, ver ⁇ tied.
• the use of the heating medium circuit may have advantages in terms of. have the effectiveness of heating and a uniform distribution of heat in the body suit.
• the heating medium circuit comprises a multiplicity of lines which are distributed in the body suit and form one or more ring lines (partial circuits).
• the cladding material is constructed in multiple layers from at least two cladding layers (layers).
• the multilayer structure has advantages in terms of adaptation of the cladding material to a mechanical protection and sealing function and to a thermal insulation function.
• a Man be ⁇ tel slaughter formed of a material outside that is formed for the Ab ⁇ seal and mechanical protection, while a further, inner cladding layer forms an insulating layer.
• Particularly preferred is a structure in which the outermost coat ⁇ layer a gas-tight outer skin, for example of poly ⁇ mers, z.
• PTFE MetallVaporonne, silicone coating, ceramics or paints
• the inward stabilizing layer for example, from textile fabrics, metal fabrics and nets, cellulose composites, plastic nets, carbon fabrics, tear-resistant films, rubber or combinations of these materials
• the insulating layer eg from polymer foam, polystyrene, silicone foam, glass wool, vacuum insulation boards, wood, cork, mineral wool, powder.
• a heating area can form a separate, innermost jacket layer, at least parts of the heating unit, such as the heating layers or the lines of the heating medium circuit, being arranged in the heating area.
• the insulation layer can optionally be equipped with a heat-reflecting film, for example a metal foil-coated plastic film.
• Jacket material can carry even more layers especially on its outside.
• the insulating layer is formed of a plastic material having a thermal conductivity below 0.1 or 0.05 W / (m-K).
• the jacket material contains at least one inflatable or evacuated intermediate layer, which is preferably arranged inside or outside adjacent to the heating area.
• the jacket material of the body suit is flexible.
• the flexibility is realized at any temperature in the cold room by at least the outer layers of the jacket material are formed from a -200 ° C flexible plastic and / or heated by the heater to a temperature above -200 ° C, in which the outer Layers of the jacket material are flexible.
• the jacket material of the body suit is rigid, wherein parts of the
• Body suits are connected via joint areas.
• fewer requirements are placed on the materials of the outermost cladding layers and / or their heating in this case.
• the joint areas must be heated in order to remain flexible at a low temperature.
• the position of the heating device in the layer composite and the thermal conductivity of the materials used are chosen so that a heat flow from the heater for the most part to the inside flows and flows to a lesser extent to the outside.
• more than half, preferably more than 75% of the heat flow flows inward, while the remaining heat flow flows to the outside and heats the outer jacket or Ge ⁇ steering area layers.
• the heater is operated with such a power that inside the
• Protective suit reaches the physiologically acceptable temperature and the outer jacket or hinge region layers are heated to a temperature at which they even at a surrounding ⁇ ambient temperature below z. B. -90 ° C are flexible.
• the position of the heater can be, for example so- ⁇ selects that this is arranged on the inner surface of the jacket ⁇ materials.
• the inside of the suit can be heated particularly effectively.
• the cladding material would be selected with a small thickness. In this variant, there is an increased energy consumption of the heater, but due to the small thickness of the jacket material, a low weight of the suit and its easy mobility is achieved.
• the heater may be embedded in the depth of the jacket ⁇ material.
• the portions of the heat flow emitted by the heating device, which flow in or out, can be selected such that the outer jacket layers and the interior of the heater.
• Protective suits can be effectively warmed and still maintain a good thermal insulation of the operator from the environment.
• the body suit is provided with flexibility of the sheath ⁇ material on a front side with a manhole on which layers of the cladding material are arranged overlapping each other.
• a step-shaped overlapping area is provided in the case of the multilayer structure of the jacket material.
• the access opening is preferably provided in a shoulder region or a body region of the body suit.
• rigid or flexible connecting elements may be provided which lock when Zusmen menhegen and the interior of the suit abdich ⁇ th.
• the body suit of the protective suit according to the invention can be equipped with a helmet.
• the helmet is disposed on the upper part of the body suit, and at its head is rich ⁇ tet for a gas-tight enclosure ⁇ the operator.
• the helmet comprises a mechanically stable, the head of the operator completely surrounding and gas-tight with the body suit connected component which has a transparent front window at least in the viewing direction of the operator.
• the helmet has a shape that is adapted to the shape of the head, in particular the shape of a ball or a spherical section. If at least the windscreen, preferably the entire helmet, is formed from a double-walled, evacuated disk material, there are advantages for the thermal insulation of the interior of the helmet.
• a ball or a ball section of a double-walled, evacuated material is provided.
• the helmet can take on at least one of the following additional functions of the protective suit.
• a pressure relief valve may be provided on the helmet, over which in case of malfunction of the breathing air supply, an overpressure in the suit can be reduced.
• the helmet can be equipped with a disk heater to improve the operator's view.
• the disc heater consists eg of a transparent heating material, such as ITO (indium tin oxide).
• the helmet can be equipped with a rear-view mirror, which improves the operator's view to the rear and reduces the demands on the mobility of the suit.
• the helmet can be equipped with a coupling device, via which the protective suit through a supply line with a wide ⁇ ren protective suit or an emergency relief center ⁇ can be verbun.
• a coupling device via which the protective suit through a supply line with a wide ⁇ ren protective suit or an emergency relief center ⁇ can be verbun.
• the body suit is equipped with a belt device which preferably surrounds the body part and optionally parts of the leg parts.
• a belt device which preferably surrounds the body part and optionally parts of the leg parts.
• an external support means e.g. a tether, be coupled.
• the operator can be reliably pulled out of the cold room in the suit by means of the support means.
• the belt device can be used for attaching loads to the protective suit.
• the protective suit according to the invention can be equipped with an emergency supply device which has a respiratory air reservoir in the protective suit and / or a coupling insert. direction for connection to an external supply device.
• the breathing air reservoir comprises eg a compressed air cylinder, a heating cartridge and a valve-controlled connecting line between the compressed air cylinder and the inside of the protective suit.
• the breathing air reservoir can be integrated into the helmet of the body suit, for example.
• a lighting device for illuminating the surroundings of the protective suit
• a sensor ⁇ device for detecting the oxygen content, the temperature and / or physiological properties of the operator
• an alarm to warn the operator of unwanted Operating conditions
• a communication device for wireless or wired communication of the operator with other assistants in or outside the refrigerator.
• the protective suit according to the invention has shoes for receiving the feet of the operator.
• the shoes are made for use in cold rooms, which are typically cooled from the ground using liquid nitrogen, special requirements in terms of mechanical and thermal protection of the operator.
• the shoes have at least one of the following features.
• the platform soles offer the possibility of effective thermal insulation and increase the distance of the shoes from a cooling device provided in the bottom of the cooling chamber with liquid nitrogen.
• the platform soles can be equipped with sole profiles, which allow a reduction in the contact area between the shoe and the ground.
• the shoes can be equipped with sole cavities. These include gas-filled or evacuated areas in the soles.
• this improves the thermal insulation of the shoes.
• the shoes can be provided with protective layers against mechanical injuries, eg using ceramics.
• the interior of the shoes is sized to provide adequate room for movement of the foot in the shoe, even when the operator is wearing thermal insulation clothing.
• flexible adjustment elements are preferably provided in the leg part, or in the shoe, the son for receiving a part of the leg or of the foot of Consper- and Support in the protective suit are configured.
• the protective suit according to the invention can be connected to an external breathing air supply via a supply line, in particular a heated hose line.
• a respiratory air source is provided in the protective suit.
• the source of breathing air is adapted to supply breathable air to the interior of the suit.
• the breathing air source is housed in a back part of the protective suit.
• a portion of the heater is configured to heat the air provided by the source of breathing air.
• the breathing air source has the additional advantage that the protective suit can be subjected to an overpressure compared to the environment in the cold room.
• the overpressure can be chosen so that the protective suit physiological breathing conditions are given and unfolds the interior of the body suit or parts of this under the effect of the internal pressure (inflated).
• an additional thermal insulation is thus achieved.
• the suit may be equipped with a compressed air source independent of the source of breathing air to produce the overpressure.
• the protective suit according to the invention with Minim ⁇ is equipped least a glove for receiving a hand of the operator.
• the glove is formed from a thermally insulating glove material and provided with an electric and / or a supplied with heating glove heater.
• the glove may be integral with or separable from the body suit.
• the glove material is preferably constructed like the jacket material.
• the glove can be used to manipulate refrigerated items, regardless of body suit on refrigerators. Therefore, the glove, as such, represents an independent Jacobs ⁇ tand the present invention.
• the at least one glove comprises at least two, preferably before ⁇ at least three, more preferably five fingers chambers which are individually movable.
• the at least one glove allows the gripping of objects, such as sample containers in the cold room.
• the interior of the at least one glove is dimensioned such that at least the fingers, preferably the entire hand, of the operator in the glove is freely movable.
• the glove is provided with retaining elements configured to receive or support part of the hand, wrist or forearm of the operator in the glove are.
• the hand can be moved in the glove so that the fingers are in different positions relative to the glove. In a first position, the fingers may be located near the glove heater, preferably on the back of the glove. In a second position, the fingers may abut the handle sides of the finger parts to grip an object.
• the finger chambers of the at least one glove are equipped with gripping regions in which the glove material has a reduced thickness compared to the rest of the glove.
• the gripping areas are arranged and dimensioned so that contact surfaces can be formed between adjacent fingers, as they are when gripping an object with one hand without a glove.
• the thermally insulating glove material is designed to be particularly thin in the grip areas, in order to obtain a finger pressure sensor system for the operator.
• the gripping areas allow the operator to have a feeling for gripping an object.
• the grip areas on the outside of the glove may have a profiled surface. This enables a secure gripping of even small objects, such as e.g. Sample tubes or the like.
• the at least one glove is particularly preferably configured to be subjected to an internal pressure such that there is sufficient space inside the glove for a movement of fingers from a gripping position with contact of the fingers with the glove material, in particular the gripping areas, into a heating position without contact of the fingers with the glove material is formed.
• the glove is in combination with the rest of the body suit or a cooling system, eg. B. inflatable with dry or warm air to form the internal pressure.
• the at least one glove can be equipped according to a further variant of the invention with recordings for sample carriers.
• the recordings for sample carriers are e.g. arranged on an outer side of the glove and serve the intermediate storage of a removed from a rack device sample carrier before its transfer to another Regaleinrich- device or a transport container.
• the protective suit according to the invention has the following further advantages. Due to the internal respiratory air source with temperature control, the suit can be used in the cold room in air or in a pure nitrogen atmosphere. It is a good mobility of the limbs of the operator even at low temperatures, e.g. given to -190 ° C or below. In the protective suit, a physiological temperature of the operator can be maintained. The temperature may be regulated by the operator or automatically adjusted by a controller. The suit allows a quick on or off by the operator, which is beneficial for both the normal operation of the cooling system as well as for the accident. The at least one glove offers a good grip for the hands with a safe physiological tempering.
• FIGS. 1A and 1B show two embodiments of a protective suit according to the invention
• FIG. 2 schematic cross-sectional views of FIG
• FIG. 3 schematic cross-sectional views of FIG
• Jacket material of a body suit provided with a heating medium circuit
• FIG. 4 shows schematic cross-sectional views of further embodiments of the jacket material of the body suit
• FIGS. 5A and 5B schematic cross-sectional views of a
• Figures 6A and 6B are schematic cross-sectional views of a
• FIGS. 8A to 8C schematic illustrations of further ⁇
• FIG. 9 the interaction of gripping regions of gloves according to the invention.
• Figure 10 a schematic illustration
• FIG. 14 is a block diagram illustrating the illustration
• FIGS. 1A and 1B schematically illustrate two embodiments of the protective suit 100 according to the invention
• Protective suit 100 each includes a body suit 10 of a jacket material 20 (see FIGS. 2 to 4) with a helmet 40 (see FIG. 5), shoes 50 (see FIG. 6), a back piece 60 with a breathing air source (see FIG. 14), and a hand shoes 70 (see FIGS. 7 to 11). Furthermore, the protective suit 100 comprises a schematically shown heating device 30 (see FIGS. 2 to 4).
• the body suit 10 includes two leg portions 11 for receiving the legs, a body portion 12 for receiving the trunk and two arm portions 13 for receiving the arms of the operator 1.
• the overall composite of the jacket material 20 with a manhole and the coupling between body suit 10 and helmet 40 are gas-tight educated. They are particularly impermeable to moisture (water vapor) to to keep a cold room when entering by the operator 1 in the protective suit 100 ice and frost.
• the sheath material 20 is a laminated structure of a plurality of directly superimposed cladding layers. Inflatable or evacuated intermediate layers are not provided in this case.
• the materials of the cladding layers and the layer sequence are chosen so that the majority of the heat emitted by the heater 30 flows inwardly, while the cladding material 20 heats up to the outside so that it remains flexible even at low temperatures in the refrigerator.
• the required surface temperature of the jacket material 20 does not necessarily have to be set above 0 ° C.
• the protective suit 100 forms a pressure suit.
• an increased internal pressure in the jacket material 20 and / or in the interior of the body suit 10 is set therein, so that the jacket material 20 bulges outward.
• the sheath material 20 has a greater wall thickness compared to the embodiment of FIG. 1A.
• the cladding material 20 is at least ⁇ rigid at low temperatures in the cold room. Nevertheless to ensure the free movement of the operator 1 in the protective suit 100, the hinge portions 14 are provided.
• an access opening for loading ⁇ serving person 1 20 may be formed along an opening line 16 by an interruption of the cladding material.
• a closure such as a bayonet closure, Velcro closure with elastic and sealing bands, to open or close the manhole.
• the access opening is provided by a two-part construction of the body suit 10.
• the jacket material 20 is interrupted.
• the coupling rings 17 are designed for a gas and pressure-tight coupling of the parts 11, 12. They form one example Baj onettver gleich having provided between the Kopplungsrin ⁇ gen 17 sealing layer.
• the heating devices 30 shown schematically in FIGS. 1A and 1B comprise, for example, electrical heating layers or lines of a heating medium circuit, as described in more detail below.
• the parts of the heater are distributed in the body suit 10 and / or in the back 60. They are particularly useful in areas where ned in which flows a relatively large amount of heat when used in the refrigerator, such as the leg and arm portions 11, 13.
• In the shoes 50 and gloves 70 are preferably electrical ⁇ cal heating elements such as heating layers provided.
• the helmet 40 is attached to a coupling ring 18 at an upper En ⁇ de body suit 10 gas-tight and locked.
• a hinge may be pre see ⁇ on which the helmet 40 can be folded in a non-locked state to the rear, to facilitate the exit of the operator 1 of the protective suit 100th
• the back section 60 may be fixedly connected to the jacket material 20 or coupled to the body suit 10 via belts like a backpack.
• the breathing air source a part of the heating device for heating the breathing air
• a power source in particular a battery
• a control device in particular a control device
• an additional compressed air source in particular a battery
• the back section 60 is coated from a thermally insulating material, such as carbon cloth, Harzver ⁇ composite foam, glass wool composite material, expanded polystyrene formed to protect the components mentioned before Un ⁇ supercooling.
• the shoes 50 and the gloves 70 may be permanently connected to the body suit 10. Alternatively, a separation of the shoes 50 and / or the gloves 70 from the body suit 10 is provided. In this case, the shoes 50 and the gloves 70 are provided with coupling elements (see FIG. 7) in order to form a gas-tight and optionally pressure-tight connection with the body suit 10.
• the front ends of the shoes 50 (toe tips) are mechanically reinforced and insensitive to contact with liquid nitrogen.
• the shoes are 50 this made of plastic material or ceramic, as they are used in conventional cryogenics for cryogenic tanks.
• FIG. 1A furthermore illustrates the optionally provided belt device 15.
• the belt device 15 can be embedded in the jacket material 20 or arranged on the surface of the jacket material 20. At the belt device 15, a tether 210 is fixed, with which the operator 1 can be secured in protective suit 100 or lifted in an accident situation from the refrigerator.
• the use of the protective suit 100 according to FIG. 1A takes place in such a way that first the helmet 40 is folded back and the body part 12 is opened along the opening line 16.
• the operator 1 enters the body suit 10.
• the operator 1 can wear normal clothing or a warming textile clothing (lined textiles), eg a lined headgear (hatched).
• the manhole is closed along the opening line 16 and the helmet 40 folded forward and ge ⁇ closed on the coupling ring 18.
• breathing air source is operated in the back 60 to the operator 1 with breathing air to versor ⁇ gen. In this situation, the operator ready in protective suit 100 to enter a cooling chamber.
• the cooling space comprises, for example, a floor area, side walls and a ceiling area, wherein a cooling device for cooling the cooling space using liquid nitrogen is arranged at least in the floor area.
• the side walls are typically formed closed (without a door opening). Access to the cold room is through an opening in the ceiling area.
• a work platform is arranged, on which the operator in protective suit 100 moves can, for example, to carry out maintenance work or to receive or deposit sample containers.
• FIG. 1B provision is accordingly made for the operating person 1 first to get into the leg parts 11 of the body suit 10 and then to put on the torso and arm parts 12, 13 and the helmet 40.
• the protective suit 100 is closed gas-tight and pressure-tight on the coupling rings 17.
• the source of breathing air in the back part 60 is put into operation to provide the operator 1 with breathing air.
• connection to an external power source may be provided via a supply line 220, which is shown schematically in Figure 1B and in further detail in Figure 13.
• Figures 2A and 2B show two variants of Mantelmateri- as 20, which is preferably provided in the embodiment of the protective suit 100 according to Figure 1A.
• the cladding material 20 from the outside comprises inwardly a gas-tight outer skin 21, a stabilizing layer 22, an insulating layer 23 with a heat reflecting foil 24, egg ⁇ NEN heating region 25, a memory layer 26 with an inner skin 27 and a fabric layer 28.
• the outer skin 21 comprises a gas-tight composite material which contains a tissue, for example coated plastic nets, Glaswol ⁇ le, carbon fabric, laminated film, and / or coated foam.
• the thickness of the outer skin 21 is z. B. 0.5 mm to 3 mm.
• the stabilization layer 22 is likewise a composite material into which a mechanically stable lattice material rial, for example made of a plastic, is embedded.
• the thickness of the stabilization layer 22 is for example 0, 1 mm to 2 mm.
• the heating region 25 comprises heating layers which are uniformly distributed in the jacket material 20, arranged in layers.
• Heating layers are connected via electrical lines (not Darge ⁇ asserted) supplied with the power source in the back part 60 (see Figure 1) and / or are connected via the supply line 220 to an external power source.
• the storage layer 26 comprises a material having a high heat capacity, such as paraffin, wax, magnesium composite, graphite, foam polystyrene, wood components with a specific heat capacity greater than 1 kJ / kg K. It has a thickness of eg 2 mm to 10 mm.
• the storage layer 26 serves as a heat buffer and for distributing the heat.
• the inner skin 27 has a mechanical stabilizing function.
• the textile layer 28 consists of a textile material or felt in order to make the inner contact between the operator 1 and the jacket material 20 as comfortable as possible.
• the body surface 2 of the operator 1 is in direct contact with the inside of the lateral surface 20.
• the body surface 2 is directly warmed by the jacket material 20.
• the breathing air is supplied to the body suit 10 with a pressure which is selected above the outside atmospheric pressure in the cooling space.
• the jacket material 20 is inflated so that between the inside of the jacket material as 20 and the body surface 2 of the operator 1, a distance 3 (eg a few centimeters) is formed.
• the generation of the distance 3 between the operator 1 and the Mantelma ⁇ TERIAL 20 has the advantage of a thermal buffering and a uniform distribution of the heat inside the compassionan ⁇ train 10th
• FIGs 3A to 3C illustrate a modified version of the jacket material 20 and the suit 100, wherein the heating device by a heating medium 33 with Lei ⁇ obligations 34 is formed 35th
• the lines 34, 35 form at least one closed loop.
• the heating ⁇ medium circuit 33 includes a plurality of lines 34, 35 for a gaseous or liquid heating means. If the heating medium is a liquid, eg water, alcohol or a fluid oil, advantages result from the high heat capacity of the heating medium.
• a disadvantage may be the relatively high weight of the protective suit 100 and the Havariegefahr at a leakage of Schuitzniks.
• the body suit 10 consists of several parts (see FIG. 1B)
• the lines between the parts are coupled in the assembled state of the body suit 10.
• valves are arranged in the lines, which prevent leakage of the liquid.
• the jacket material 20 is a multilayer with a gas-tight outer skin 21, a stabilizing layer 22, an insulating layer 23, which carries a heat reflection film 24, a Heating region 25, in which the lines 34, 35 are arranged, an inner skin 27 and a textile layer 28 constructed, as described above with reference to Figure 2A.
• the lines 34, 35 are arranged distributed in the jacket material 20.
• the lines 34, 35 extend annularly around the extremities of the operator 1, while in the body part 12, the lines 34, 35 extend annularly around the trunk of the operator 1.
• the at least one ring line is connected to a heating medium heater in the back part 60 (see FIG. 1) or to an external heater.
• the lines 34, 35 are placed so that the supply of the warm heating means from the Schuffenracung (line 34) alternates with the return to the cooled heating means (line 35).
• the feeds with the warm heating means (line 34) are arranged in an inner layer of the heating area 25, while the returns with the cooled heating means (line 35) are arranged in an outer layer of the heating area 25.
• the SchuffenSullivanung supplies the heating means with a temperature of z. B. 15 ° C to 30 ° C.
• the use of line connections and valves can be avoided if, according to FIG. 3C, the access opening of the protective suit 100 is arranged above the trunk and arm parts 12, 13.
• the heating medium circuit 33 may be arranged as a closed line system without interruption in the jacket material 20 of the body suit 10.
• Figure 3C further illustrates a star-shaped manifold 36 for exposing the leg, torso and arm parts 11, 12 and 13 to separate flows of heating means.
• Modified variants of the cladding material 20, which have advantages in terms of thermal insulation and the reduction of the necessary heating power, are illustrated in Figures 4A and 4B.
• the jacket material 20 comprises an outer shell 20.1 and an inner shell 20.2. It is similar to the layer sequence in Figure 2A with an outer skin 21, a stabilizer ⁇ ltechniks slaughter 22 and a first insulating layer 23.1 is provided with a ärmerefletechnischsfolie 24, constructed. Furthermore, a second insulating layer 23. 2, likewise provided with a heat-reflecting film 24. 2, and a textile layer 28 are provided on the inwardly-facing side of the jacket material 20.
• the materials and dimensions of the cladding layers may be selected as described with reference to FIG.
• the heating region 25 is arranged with heating layers for electrical resistance heating of the jacket material 20.
• the intermediate layer 29 is not filled with gas but is formed with evacuated components 29.3 (evacuated plastic components). In this case, the heating layer 25 is provided on the inner surface of the intermediate layer 29.
• FIGS. 4A and 4B Both variants of FIGS. 4A and 4B are characterized by a reduced flexibility or complete rigidity of the invention
• FIGS. 5A and 5B illustrate the helmet 40 of the protective suit 100 according to the invention in a schematic front view (FIG. 5A) and a cross-sectional side view (FIG. 5B).
• the helmet 40 comprises a truncated, double-walled ball of a transparent plastic material, for example copolymer (elastomers), cellulose acetate, acrylonitrile, polystyrene.
• the ball is formed by an outer wall 40. 1 and an inner wall 40. 2, which are connected to the coupling ring 18.
• the space between the outer and inner walls 40.1, 40.2 is evacuated to reduce the heat conduction from the interior of the helmet 40 to the outside.
• the front side of the helmet 40 which faces in the direction of the operator 1, forms a windshield 41, which is equipped with a glass heater 41.1.
• the inner surface of the inner wall 40.2 is mirrored, so that heat radiation inside the helmet 40 is reflected inward.
• Warmed breathing air from the breathing air source in the back part 60 is fed into the helmet 40 via a thermally insulated supply line 45. If a breathing circuit is provided, the breathing can also be via a mouthpiece with valves (not shown), so that advantageously fogging of the inner surface of the helmet 40 is avoided.
• a shock protection 40.3 is arranged, the protection against mechanical shocks and the inclusion of functional components, such as a lighting device 40.4, for example, a white light LED, an antenna 40.5 for wireless communication and / or Kochven- tils 42 serves. If the breathing air pressure in the helmet 40 increases unintentionally, a relief can be achieved with the pressure relief valve 42. Furthermore, the pressure relief valve 42 is provided with an emergency opening element 42.1.
• the helmet 40 is further equipped with a Notnumberedseinrich ⁇ device 44.
• the emergency supply device 44 is arranged on the back (occipital region) of the helmet 40. It contains a compressed air cylinder 44.1, a heating cartridge 44.2 and a valve-controlled connection line 44.3. In the event of failure of the respiratory air source in the back part 60 (see FIG. 1), the emergency supply device 44 can be actuated to direct tempered breathing air via the connecting line 44.3 directly into the interior of the helmet 40.
• helmet 40 Other functional elements of the helmet 40 include a microphone 40.6, ear speaker 40.7, an emergency button 40.8, which can be actuated by a movement of the head of the operator 1, and a rearview mirror 40.9.
• FIGS. 6A and 6B show the shoe 50 of the body suit 10 according to the invention (see FIG. 1) in a schematic longitudinal sectional view of the front shoe area (FIG. 6A) and in a reduced sectional side view (FIG. 6B).
• the design of the shoes 50 is of particular importance to the safety of the operator since the shoes 50 come into direct contact with the coldest surfaces in a cold room.
• a cold room At the bottom of a cold room is located eg in a thermally insulated pan an open nitrogen lake, which is covered with a grid. On the grid, the operator 1 moves in the protective suit 100. The temperature at the bottom is almost equal to the temperature of the liquid nitrogen, ie at about -195 ° C.
• the shoes 50 are configured to ensure safe protection of the operator's foot 4, even when liquid nitrogen is sprayed up from the ground or is placed in the liquid nitrogen with the shoe 50 in an emergency situation.
• the nitrogen lake of a cooler of the cold room in the thermally insulated pan typically has a depth no greater than 5 cm.
• the shoe 50 is therefore equipped with a platform sole 51 and designed so that the foot sole 5 of the operator 1 has a distance h above the ground that is greater than the depth of the nitrogen lake of the cooling device.
• the distance h is, for example, greater than 5 cm, in particular greater than 6 cm.
• the bottom of the shoe 50 is formed so that the shoe 50 is impermeable to liquid nitrogen.
• the platform sole 51 and the upper shoe area 52 are therefore formed from a low-temperature-resistant plastic material, eg PTFE, ceramic, glass composite, carbon laminate.
• a protective layer 53 is disposed against mechanical injuries, which consists for example of a ceramic, a metal mesh or a plastic mesh.
• the platform sole 51 has a sole profile 51.1 (see FIG. 6A) with which the tread resistance is improved and at the same time the contact surface with the ground is reduced.
• evacuated cavities 51.2 are provided in the platform sole.
• a heat reflection layer 54 for example a plastic film coated with aluminum, and an insulation layer 55, for example made of polymer foam, are arranged inside the shoe 50.
• an insulation layer 55 for example made of polymer foam
• an electrical heating layer 37 Arranged on the surface of the heat reflection layer 54 is an electrical heating layer 37 (shown dotted) which extends on the underside of the foot 4 and optionally also on the sides or top of the foot 4.
• the insulating layer 55 includes a gas-filled interior 56 of the shoe 5 for receiving the foot 4.
• the interior ⁇ space 56 is formed significantly larger than a human footwell would need. This allows the operator to wear additionally lined textiles and the shoe 50 can be used by persons with different foot sizes.
• 50 flexible adjustment elements 58 are arranged in the shaft 57 of the shoe. The adjustment elements 58 give the upper part of the foot 4 and / or the lower leg 6 sufficient support to be able to transmit the required force to the shoe 50 during movement.
• the insulating layer 55 merges into a shoe insert 55.1, which consists of an elastic and heat-reflecting material, such as metal-coated plastic films, PTFE films, felt layers, foam layers, glass laminates.
• the shoe insert 55.1 is used for the thermal insulation of the foot 4 and the improvement of the fit of the shoe 50th
• the use of the hands is of particular importance to the operator who is in the protective suit in the cold room, for example during maintenance work or when taking sample containers from a shelf.
• the gloves 70 see Figure 1
• the operator comes into direct contact with cold surfaces.
• Sample containers with small dimensions, such as sample tubes with a size of a few centimeters, must be securely gripped and held with the gloves for this, a mobility of the fingers is required, while at the same time a heat transfer from the fingers to the sample container is to be minimized.
• the glove of the invention is adapted for use in conjunction with the protective suit, or alternatively with a refrigeration system (e.g., cool box or freezer) under normal pressure at temperatures as low as -200 ° C.
• a refrigeration system e.g., cool box or freezer
• the glove can be connected to supply and control systems which, depending on the design of the glove heater (in particular electric resistance heating or
• the compressed air source is connected to a part of the heater for air heating and air drying and with a flow control for adjusting the effluent from the glove exhaust air.
• the sensor device preferably comprises temperature sensors in each finger chamber and in the back of the hand and the palm of the glove. Furthermore, sensors for detecting the air pressure and the air flow in the glove may be provided. The sensor device is connected to an alarm device in order to be able to signal unwanted operating states in the glove.
• the heater is configured as described above with respect to the heater in the body suit and will be discussed in further detail below. The features mentioned are met by inventive gloves 70, the in preferred embodiments are shown in Figures 7 to 11.
• the glove 70 with a plurality of finger chambers 73 is produced from a thermally insulating glove material 71, which forms an inner space for receiving the hand of the operator.
• the glove material 71 is generally multi-layered and constructed like the shell material of the body suit, optionally without the storage layer.
• the thermally insulating glove material 71 comprises, from outside to inside, a gas-impermeable, cold-resistant outer skin 71.1 and at least one insulating layer 71.2.
• the outer skin 71.1 comprises a composite material, such as e.g. a bonded with a binder tissue.
• the insulating layer 71.2 consists e.g. of metal-coated plastic material PTFE film, carbon composite material, felt fabric, paraffin or wax composite material and laminates.
• a heat reflection film for rear reflection of heat radiation is disposed inside the glove 70.
• the thermal insulating glove material 71 can have a simplified structure and a reduced insulating ability. However, this is not critical for the practical use of the protective suit according to the invention, since the gloves 70 form only a small heat source compared to the remaining surface of the protective suit.
• heating layers (heating foils) 77 are disposed for electrical resistance heating. The heating layers 77 are arranged so that heat is conducted in particular into the environment of the forearm, the palms and the fingers becomes. It can be provided that in the front part of the gripper fingers (thumb, forefinger, middle finger) only the top of the gloves 70 (side facing the back of the hand) is heated.
• Gripping areas 74 are provided on the gripping surfaces of the finger chambers 73 for the gripping fingers, in which the thermally insulating glove material 71 has a reduced thickness of less than 1 cm, in particular less than 0.5 cm, compared with the rest of the glove 70.
• the grip regions 74 advantageously allow a finger pressure sensor system to be utilized in spite of the low temperature and to give the operator a feeling for the grip.
• the outer surfaces of the gripping regions 74 are covered with a profiled, flexible material which has advantages for gripping the sample containers. The profiling of the gripping regions 74 reduces the risk of slipping out of sample containers.
• the thermally insulating glove material 71 is heated from the inside so that the outer surface (outer skin 71.1) of the thermally insulating glove material 71 remains flexible and flexible.
• the temperature of the skin 71.1 is e.g. set in a range of -10 ° C to -60 ° C.
• FIGS. 7A and 7B are illustrated with a schematically shown coupling element 76, which is designed to connect the glove 70 to the arm part 13 of the body suit 10 (see FIG. 1).
• the coupling elements 76 are connected to an outer wall of the cooling system so that an operator's hands from the outside in the gloves can be stuck.
• a connection is made to an external power source for supplying the electric glove heater via the coupling elements 76.
• the gloves 70 are separable from the body suit 10.
• gloves can thus be replaced depending on the specific requirements of the application in the cold room and the size of the hand of the operator.
• the coupling elements 76 are receptacles 75 for sample containers, such as e.g. Sample tube provided.
• the receptacles 75 are adapted to the shape of the sample container. For example, quivers are provided for holding sample tubes (so-called "straws"), while a box or a towing device is provided for receptacle-type sample containers as a receptacle 75.
• the receptacles 75 have the advantage that sample containers can be temporarily stored, but not between 7, it is however possible for the gloves 70 to be firmly connected to the arm parts 13 of the body suit 10, notwithstanding the illustrations in FIG.
• FIG. 7B shows an embodiment of the glove 70 used in combination with the pressure suit of Figure 1B.
• 76 are in the coupling element lines for incoming (76.1) and outgoing (76.2) gases.
• the glove 70 is heated and inflated by the incoming warm gas (temperature, e.g., 25 ° C to 35 ° C).
• heating layers may be provided inside the glove 70, as described with reference to FIG. 7A.
• retaining elements 72 are provided in order to To support a part of the hand 6 or the forearm of the operator in the glove 70.
• Retaining elements 72 include, for example, one or more rings, which surround the glove 70 in the region of the wrist. The holding elements 72 allow a slip in and out of the hand 6 and at the same time give the
• a particular advantage of the glove 70 according to FIG. 7B is that in the event of hypothermia of the fingertips or another emergency situation, the arm of the operator can be withdrawn and a fist can be formed (shown in dashed lines in FIG. 7B). In this situation, rapid warming of supercooled limbs is possible.
• the conduit for the incoming (76.1) gas may, by derogation of the illustration, preferably be formed so that the gas at the outermost end of the glove 70 between the fingertip and the end of the finger chambers 73 flows into the glove 70 and then along the fingers over the hand flows in the direction of the wrist in order to achieve rapid warming of the fingers and hand and a distance between the fingers and the glove filled with flowing gas. It is advantageous if, in addition to the pressure, the flow of the gas is maintained constant, especially in its flow direction.
• the glove 70 according to the invention can be provided, for example, as a three-fingered glove or as a five-fingered glove, as shown schematically in FIGS. 8A and 8B.
• a finger chamber 73 is provided for the thumb and forefinger of the operator and a further finger chamber 73 is provided for the remaining fingers of the operator.
• a part of the heater 30 is arranged in each of the finger chambers 73.
• the heating Direction 30 a Walkerstoffniklauf with a line 34 for supplying the heated heating means and a line 35 for returning the cooled heating medium, which are split at a distributor 36 on three loops.
• five finger chambers are respectively provided for receiving one finger each of the operator. In this case, the lines 34, 35 of the heater 30 are split at the manifold 36 on five loops, each extending on the back of the hand of the glove 70.
• Figures 8A and 8B further schematically illustrate a pressure line port 76.3 with a conduit for supplying a pressurized gas, e.g. Compressed air, in the glove 70 and a line for the flow of compressed gas.
• a pressurized gas e.g. Compressed air
• the overpressure creates between the hand of the operator and the inner surface of the glove 70 a gas-filled space in which the hand of the operator is movable (see Figure 7B).
• the pressure line connection 76.3 is guided by the coupling element 76 (see FIG. 7B) and is connected to a compressed gas source.
• FIG. 8C schematically illustrates that the glove 70 according to the invention can also be equipped with a joint region 14, which in this case forms a gripping fold on the thumb of the glove 70.
• the grip fold is constructed, for example, as explained below with reference to FIG.
• the glove material may be modified in the area of the thumb fold to ensure the flexibility of the glove.
• an interruption in the layer composite of the glove material for example a gap or a region with a reduced thickness of the insulation layer 71.1 (see FIG. 7A), may be provided in the region of the thumb fold.
• FIGS. 9 and 10 illustrate further details of the gripping regions 74 on the finger chambers of the glove 70 according to the invention. According to FIG. 9, the gripping regions 74 on the parts of the finger chambers for receiving the thumb and of the fingers
• the grip portions 74 are arranged so as to be opposed to each other in the case of a glove 70 closing to a grip.
• the grip regions 74 are characterized by a reduced thickness of the glove material in comparison to the rest of the glove. As a result, the sense of touch for the operator is maintained in the grip areas 74. Safe holding, e.g. of sample containers is ensured because the holding force can be manually controlled and unintentional slipping of the sample container can be avoided.
• the grip regions 74 in conjunction with the application of the internal pressure to the glove, represent a particularly important feature of the gloves according to the invention.
• the finger chambers are formed on the inside of the finger with the thinner, profiled material for the sensitive gripping of even small objects.
• the grip portions 74 when in contact with an external solid which is very cold, cause the operator's fingers to cool in the contact area.
• the layers are formed so that the contact even at a temperature of the solid -200 ° C can easily exist for minutes. After the release of a held object, the warming of the cooled-off finger areas of the operator takes place.
• This heating is inventively achieved in that after release of the handle by the internal pressure in the glove, the finger berries are no longer in contact with the glove material, so that they are warmly flowed around by the inner medium in the glove and heat up quickly.
• the pressure in the glove is chosen so that when gripping no great mechanical resistance must be overcome in order to bring the finger surface with the jacket material in contact.
• This glove finger principle is particularly advantageous for repeated gripping and depositing of objects, as used in cryobanks.
• FIG. 10 illustrates a variant of the glove 70 in which the glove heater is formed by a heating medium circuit.
• handle portion 74 is enlarged in the schematic sectional view of the glove material shown in FIG. 11 11 shows a grip region 74 in the glove material, which in this example is formed with a gas-tight outer skin 71.3, a stabilization layer 71.4, an insulation layer 71.5 with a heat-reflecting film 71.6, a heating region 25, a storage layer 71.7 with an inner skin 71.8 and a textile layer 71.9.
• a gap in the storage layer 71.7 in the glove material with a lateral dimension of z. B. release 2 cm.
• a joint region 14 comprises a movable link part 14.1.
• the link part 14.1 is located between rigid, tubular components 13.1, 13.2 of the arm part.
• the link part 14.1 is worked into the glove material.
• the Gelenkbe ⁇ rich 14 has the structure of a bellows connection. Relative to each other movable ribs 14.2 are connected to each other via a flexible composite material 14.3.
• the composite material al continues from the outside to the inside of a gas-tight, mechanically robust outer skin 14.4, a mechanical coupling layer 14.5, a heating region 25 and an insulation layer 14.6 ⁇ together.
• the mechanical coupling layer 14.5 includes fully, for example, a mesh material through which the ribs are connected to 14.2 ⁇ today.
• the heating region 25 is vorgese ⁇ hen for an electrical resistance heating of the joint area fourteenth This allows the entire articulation area to be mobile even at outdoor temperatures as low as -200 ° C.
• the increased heat losses at the joint areas can be made to ⁇ because of their small size compared to the total surface of the body suit and because of the importance of their function into account.
• Other joint regions 14 provided on the body suit 10, such as leg or hip joints or the grip folds of the glove, are constructed similarly as shown in FIG.
• the supply lines When the protective suit according to the invention is connected via supply lines (electrical lines, heating lines) with external devices, the supply lines must be passed through the refrigerator and protected against destruction at low temperatures. This is illustrated schematically in FIG. 13 using the example of an electrical line.
• the supply lines are preferably made expandable. This is achieved by the spiral shape (FIG. 13A).
• the spiral supply line is elastic and adaptable in length to the specific conditions of use in the cold room.
• the supply line 220 is electrically heated, as shown schematically in FIG. 13B.
• a heating layer 223 with a heat reflection foil (not shown) is arranged inside the supply line 220.
• a thermal insulation layer 224 On the outside of the heating layer 223 is a thermal insulation layer 224, which is surrounded by a flexible, liquid nitrogen-resistant shell layer 225.
• the heating layer 223 is supplied with electric current in such a way that the temperature of the supply line 220 is increased to its surface.
• the heating of the supply line 220 is preferably carried out with a power source in the back part 60 (see FIG. 1).
• a power source in the back part 60 (see FIG. 1).
• Other lines such as Pressure lines, liquid lines or vacuum lines are constructed similarly as shown in Figure 13B.
• Figure 14 shows a schematic diagram of the supply and control systems for a protective suit 100 according to the invention, with which an operator in a cold room under normal pressure at temperatures up to z. B. -200 ° C can work.
• On Schutzanzzug 100 is an operating unit 80, can be made with the signals and settings on parts of the protective suit 100 can be made.
• the supply and control systems are shown grouped around the protective suit 100, with lines schematically representing compounds (signal connections and / or material connections) with the protective suit 100.
• the supply and control systems preferably provided for operation of the protective suit 100 include a Power supply 61 (battery), the heater 30 and the breathing air source 62.
• the power supply 61 is provided with thermal insulation in the back 60 (see Figure 1) and with a capacity sufficient for heating and operating the suit for a period of 15 to 60 minutes is sufficient. It is a coupling via a supply line 220 to an external power supply, eg in the refrigerator or an adjacent operating room, provided. This makes it possible to save or charge the internal power supply 61 or to provide additional energy for special applications.
• the heating device 30 comprises the heating elements integrated in the protective suit, which are operated electrically or with a heating medium, and a heating control.
• the breathing air source 62 is also arranged with thermal insulation in the back part 60 (see FIG. 1). Both the breathing air source 62 as such as breathing air lines and valves are thermally insulated and possibly heated.
• the respiratory air source 62 is preferably based on a compressed air system or on a circulatory system with CU 2 removal and oxygen addition.
• the respiratory air is tempered with a portion of the heater 30 and possibly using sensors in protective suit 100 and a control loop.
• protective suit 100 is constructed as a pressure suit (FIG. 1B)
• Inflatable intermediate layers 29 for the thermal insulation in the jacket material 20 are exposed to air from the compressed-air source 63.
• the compressed air source 63 with a
• a radio system is connected to an antenna 40.5 for communication with the outside and other persons in the refrigerator, as well as a lighting device 40.4, a camera device 40.10 and a microphone 40.6 for a radio communication.
• the suit has a sensor device 90 with external sensors 91 (temperature, oxygen content) and internal sensors 92 (temperature, pressure, oxygen content, remaining running time, alarm signals, audible announcements) in the most varied places (extremities, body area, head).
• the shoes and there the soles of the shoes are equipped with temperature sensors.
• an alarm 64 gives an alarm (alarms or avoidances) to the operator and to the outside.
• the alarm can z. B. displayed in the windshield 41 of the helmet 40 or reflected in this and / or transmitted acoustically to the operator.
• the operator can automatically receive instructions for further behavior, e.g. Immediate leaving of the cold room, switching on the emergency power supply or coupling to an external energy or compressed gas supply.
• an emergency supply device 44 is provided, which is illustrated schematically in FIG. B. in the back of the head on the helmet 40 is integrated (see Figure 5B).
• the emergency supply device 44 may alternatively be mounted elsewhere on the suit (eg on a belt).
• the system contains a thermal air supply and its own temperature control for about 5 minutes, as well as an electrical supply for the radio, the lighting and the heating of the main tightening elements (eg the joints, feet). Furthermore, stored instructions for the various cases at predetermined programs that are communicated via radio to the outside and speech and speaker in the helmet of hava ⁇ tured person.
• the disabled person can try to save alone in the time spent announcing or being displayed, or persons within the cooling chamber and from outside can approach or rescue systems can be activated.

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• Business, Economics & Management (AREA)
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• Environmental & Geological Engineering (AREA)
• Physical Education & Sports Medicine (AREA)
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• 2011
  • 2011-02-02 DE DE102011010119A patent/DE102011010119A1/de not_active Ceased
• 2012
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  • 2012-02-01 EP EP12702764.7A patent/EP2670265B1/fr active Active
  • 2012-02-01 WO PCT/EP2012/000452 patent/WO2012104081A2/fr active Application Filing
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