A negative pressure protection system has a cover enclosing an inner space, a ventilation duct fluidly communicating with an air outlet port of the cover, a filter having an inlet end communicating with the ventilation duct, and an air exhausting device connected to an outlet end of the filter. The air exhausting device draws air out from the inner space of the cover via the ventilation duct. The air is filtered and purified by the filter and then is exhausted away by the exhausting device.

An air conditioning apparatus includes an air vacuum pump that sucks in air from a prescribed space to place the space under negative pressure, a first hot and cool air tank that contains the sucked air, first valves that adjust the flow rate of air supplied to or discharged from the first hot and cool air tank, a second hot and cool air tank that contains the sucked air while an air flow from the air vacuum pump to the first hot and cool air tank is restricted, second valves that adjust the flow rate of air supplied to or discharged from the second hot and cool air tank, and a heating and cooling device that manages the temperature of at least one of the first and second hot and cool air tanks to which an air flow from the air vacuum pump is restricted.

A control system for use with a hot work enclosure is illustrated and described herein. The control system comprises an air supply shutdown controller, at least one air supply gas detector, and an air supply shutdown module. The air supply shutdown controller is configured to receive an air supply gas detection signal from the at least one air supply gas detector in response to the presence of gas in air to be provided to the enclosure by an air supply system. The air supply shutdown controller is configured to be responsive to the air supply gas detection signal to provide an air supply shutdown signal to the air supply shutdown module to stop the supply of air to the hot work enclosure by the air supply system. The air supply shutdown module is beatable at a first position in the air supply system, and the at least one air supply gas detector is beatable at a second position in the air supply system, such that, in use, the gas-contaminated air detected by the at least one gas detector is prevented from passing through the air supply shutdown module.

A negative pressure room with a safety management system according to an embodiment of the present disclosure includes an interior space being under negative pressure and is provided in a movable form, so that the negative pressure room can be constructed promptly and economically in the event of a spreading infection, thereby enabling rapid and efficient quarantine treatment and observation of patients with confirmed and suspected infections, the negative pressure room is isolated from a general ward, thereby preventing the possibility of further infection to other patients or medical staff, and real-time monitoring whether negative pressure is appropriately generated in the interior space, air quality in the interior space, and the state of an isolated patient is enabled.

An encapsulated cleanroom system comprising a processing chamber and a storage section in which the processing chamber is stored, wherein, during operation, the pressure in the storage section is lower or higher than the pressures in the processing chamber and exterior space. The system can simultaneously prevent the entry of outside gases into its processing chamber and the leakage of the gases inside the processing chamber to the exterior space.

A base carrying a left-side panel and a right-side panel. A top panel is disposed on and extends between said side panels, wherein said base, said side panels and top panel define a pet receiving area. A blower unit disposed at a rear side of said pet receiving area drawing air in a direction from a front side to said rear side of the housing across the pet receiving area. An airflow control covering disposed on at least one of said left-side panel and said right-side panel providing a reduced airflow entering said pet receiving area through the side panel relative to a front side of the housing, wherein a negative air pressure is established within the housing while providing a primary airflow direction from said front side to said rear side of the housing to container pet hair, dander and debris within said housing.

A system and method for sampling air at multiple locations in a controlled environment. The system and method includes automatic adjustment of mass flow rates and duration of vacuum connections (either via time elapsed or indirectly by volume) based on rates set by an operator. Additionally, the system and method enables users to monitor and control aspects of the system via network-connected devices. Additionally, the system enable a vacuum pump to be disconnected from power in response to a physical emergency button, a software-based emergency stop button available on network connected devices, and an automatic power disconnection in response to an abnormal mass flow reading that could potentially impact the vacuum pump.

A base carrying a left-side panel and a right-side panel. A top panel is disposed on and extends between said side panels, wherein said base, said side panels and top panel define a pet receiving area. A blower unit disposed at a rear side of said pet receiving area drawing air in a direction from a front side to said rear side of the housing across the pet receiving area. An airflow control covering disposed on at least one of said left-side panel and said right-side panel providing a reduced airflow entering said pet receiving area through the side panel relative to a front side of the housing, wherein a negative air pressure is established within the housing while providing a primary airflow direction from said front side to said rear side of the housing to container pet hair, dander and debris within said housing.

An air-conditioning control system configured to control air conditioning in a building that includes an air-conditioning room in which an air conditioner is provided and a first air-inflow room into which air flows from the air-conditioning room. The air-conditioning control system includes: a temperature obtaining unit configured to obtain a temperature of the first air-inflow room; and a controller configured to control the air conditioner, based on the temperature obtained by the temperature obtaining unit.

A negative air discharge apparatus configured to be operably coupled to a negative air machine so as to facilitate the discharge of air from the negative air machine into the interior of a building. The negative air discharge apparatus includes a housing having a plurality of walls, a top and a bottom configured to form an interior volume. The housing has operably coupled thereto an air intake wherein the air intake is configured to be coupled to a negative air machine via a flexible air duct. The negative air discharge apparatus further includes an air discharge port proximate the bottom of the housing that is operable to discharge air from the negative air machine. The housing further includes a first access and a second access that are configured to provide entry into the interior volume of the housing and the plurality of air filters disposed therein.