A method for the development of a thermally insulating sandwich-structured laminate, such as a sandwich-structured laminate of a housing of a climate chamber for the high temperature range, with an internal wall and an external wall, can include the method steps: providing the internal wall, adhering at least one high temperature stable insulation panel onto the internal wall, positioning the external wall with respect to the internal wall such that between the internal wall and the external wall the at least one high temperature stable insulation panel and a hollow volume are developed. The method can further include filling the hollow volume with a PUR foam for the formation of a second rigid foam layer connecting the at least one high temperature stable insulation panel and the external wall.

It discloses a system for deep sediment flow culture simulating in-situ water pressure, comprising a flow culture apparatus, an inflow pressurizer and an outflow depressurizer, wherein the inflow pressurizer comprises a pressure tank, an air inlet pipe, a pressure regulating valve, a pressure-resistant container and a first support, wherein the pressure tank is connected with an air inlet of the pressure-resistant container through the air inlet pipe, the pressure regulating valve is arranged on the air inlet pipe, and the pressure-resistant container containing in-situ overlying water added with isotopes is placed on the first support, a water outlet of the pressure-resistant container being connected with a water inlet pipe of the flow culture apparatus; the outflow depressurizer comprises a porous medium pipe, a second support, a depressurized water outlet pipe and a water catcher.

The present invention relates to a chemical vapor-sensor bag with an integrated sensor array to verify the presence of specific chemical vapors inside a sealed bag. In an exemplary embodiment, a device can be sealed within a vapor-sensor bag to allow the device to be transported to and tested for contaminants at the point of use by an end user of the device. In another exemplary embodiment, a device can be coupled to a gas port on a vapor-sensor bag to allow gas within the device to be tested for contaminants. In another exemplary embodiment, gas from a device can be streamed through vapor-sensor bag by coupling the device to a first gas port on a vapor-sensor bag and allowing gas to exit the bag through a second gas port.

There is provided an image-capturing device for an environment forming apparatus used for the environment forming apparatus. The environment forming apparatus includes an environment forming chamber configured to be adjusted to a predetermined environment, and a through-hole configured to connect the environment forming chamber to an outside. The image-capturing device for the environment forming apparatus includes: a camera; an inner tubular member; an outer tubular member configured to cover the inner tubular member; and an air blower. A first ventilation space is formed by an inside of the inner tubular member, and a second ventilation space is formed between the inner tubular member and the outer tubular member. Air is blown toward the camera by the air blower via one of the first ventilation space and the second ventilation space, and is exhausted via the other of the first ventilation space and the second ventilation space.

A decontamination appliance includes a control cabinet having a control circuit and a decontamination cabinet. The appliance also includes an ozone generator that supplies ozone to the decontamination cabinet. The ozone generator is controlled by the control circuit. A hydrogen peroxide vaporizer is also controlled by the control circuit. A circulation fan circulates a stream of air through the decontamination cabinet. The circulation fan circulates ozone generated from the ozone generator and hydrogen peroxide paper generated from the hydrogen peroxide vaporizer. The decontamination cabinet further has includes trays mounted on a tray rack, and the appliance is mounted on wheels for portable use. The decontamination appliance also preferably includes a humidifier.

Disclosed are embodiments for an engineered feature formed as a part of or on a chamber component. In one embodiment, a chamber component for a processing chamber includes a component part body having unitary monolithic construction. The component part body has an outer surface. An engineered complex surface is formed on the outer surface. The engineered complex surface has a first lattice framework formed from a plurality of first interconnected laths and a plurality of first openings are bounded by three or more laths of the plurality of laths.

The invention relates to a laboratory cabinet device for storing laboratory samples with a magnetic closure for the door. It in particular relates to a tempering cabinet for tempering laboratory samples, in particular, an incubator for the growth of cell cultures.

An incubator for cell and tissue culture under controlled atmospheric conditions has a primary air flow control device that forms a primary, preferably laminar flow, air veil across an opening that allows access to the cells or tissue cultures disposed within the incubator. Preferably, most if not all of the air in the primary (laminar flow) air veil is recirculated, and a secondary air flow control device is used that forms a secondary, preferably laminar flow, air veil between the primary (laminar flow) air veil and a user of the incubator.

A protective cover that is positionable on a structure such as a table or a piece of laboratory furniture. The cover has at least three support structures positioned on a bottom part of the cover substantially parallel to each other. The protective cover also has at least two substrate fiber cement slabs built of reinforced organic and/or mineral fibers positioned between the support structures. A steel slab having a glassy and/or porcelain finish covers the fiber cement slabs and/or the support structures. The steel slab has three folds on the surface including two folds on the sides that correspond to a 90 angle relative to the flat part of the steel slab and a middle fold located between the side folds and creates a middle groove that forms two cavities at the bottom part of the steel slab.

An object of the present invention is to provide a low-temperature storage system that ensures minimal penetration of moisture into the low-temperature storage chamber from an external environment without involving an increase in size or complexity of the system configuration. The object is achieved by the configuration in this low-temperature storage system wherein a loading/unloading mechanism that carries storage objects into and out of the low-temperature storage chamber has an ancillary entry/exit preparation chamber. The entry/exit preparation chamber has a first anteroom with an interior space controlled to maintain a lower dew point than that of the external environment, and a second anteroom disposed between the first anteroom and the low-temperature storage chamber and having an interior space controlled to maintain a dew point that is between the dew point in the first anteroom and the dew point in the low-temperature storage chamber.