1. Field of the Invention
The present invention relates to air handling equipment, particularly, to air handling equipment used in air shower rooms.
2. Description of Related Art
In some manufacturing and scientific research facilities, clean rooms, free of dust and pollutants are usually required for performing operations. In order to prevent the clean room from contamination, clean room personnel often wear sanitized garments, gloves and booties when working in the clean room.
In addition, air shower rooms are also used to remove dust particles from the clean room personnel prior to their entering the clean room. However, most conventional air shower rooms have low cleaning efficiencies. Some dust particulates may still enter and contaminate the clean room.
Therefore, there is room for improvement within the art.
Many aspects of the present air shower room can be better understood with reference to the following drawings. The components in the drawings are not necessarily drawn to scale, the emphasis instead being placed upon clearly illustrating the principles of the present air shower room. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views, in which:
Referring to
The air shower room 100 includes an automatic door 101, a floor 103, two side walls 104 and a ceiling 105. The door 101, the floor 103, two side walls 104 and the ceiling 105 cooperatively define the inner space of the air shower room 100. A plurality of transparent anti-static curtains 102 are also positioned at multiple locations in the air shower room 100.
The automatic door 101 is an entrance of the air shower room 100 and has a button (not shown) to open/activate the door 101. When a worker needs to enter the air shower room 100, he/she may press the button to open the door 101. The door 101 closes automatically after a worker enters the air shower room 100. Transparent windows 1012 are formed on the door 101 allowing the inside of the air shower room 100 to be seen.
The two side walls 104 and the ceiling 105 have a plurality of air nozzles 106. The air nozzles 106 on the ceiling 105 inject high velocity air flow towards the floor 103. The air nozzles 106 on the two side walls 104 inject high velocity air flows towards a center of the room 100. The injected air from the nozzles 106, creates a vortex that blows off excessive particles from the person's body.
A bottom portion 1041 of the side walls 104 has a plurality of air vents 107. The high velocity air flow from the air nozzles 106 blows off the excessive dust particles, which may flow out of the air shower room 100 through the air vents 107.
The transparent anti-static curtains 102 are arranged in a number of spaced rows, e.g. four, each row hung from the ceilings 105. The anti-static curtains 102 are arranged to span from one side of the air shower room 100 to the other side of the air shower room 100. Therefore, the static curtains 102 divide the air shower room 100 into a number of separate areas. Each anti-static curtain 102 may eliminate static electricity from a person. In addition, when a worker passes through number of separate area, the anti-static curtains 102 of each separate area may block dislodged particles from entering the next curtained area, thereby achieving a better dust-removing effect.
The air shower room 100 has an exit 111. Adjacent to the exit 111 of the air shower room 100, an air curtain machine 109 is positioned in the ceiling 105. The air curtain machine 109 blows high velocity air downwardly from the ceiling 105 towards the floor 103 to form an air curtain. The floor 103 typically has a very smooth, metal conductive surface. Since the surface of the floor 103 has a very low friction, high velocity air can easily remove dust particles from the surface of the floor 103. Furthermore, the floor 103 is higher than the floor 201 of the clean room 200, for example, at least more than 5 centimeters. Due to the height difference between the floor 103 and the floor 201, the downward high velocity air flow creates a back air flow towards the inside of the air shower room 100. Therefore, the back flow may suck dust particles back again into the air shower room 100.
An infrared sensor (not shown) is positioned in one side wall 104 adjacent to the door 101. The infrared sensor is used for controlling the air nozzles 106. The sensor detects the presence of workers in the room 100 and activates the air nozzles to start blowing air. When the air shower room 100 is not in use, the infrared sensor deactivates the air nozzles 106 to be shut off/stop working.
It is believed that the present embodiments and their advantages will be understood from the foregoing description, and it will be apparent that various changes may be made thereto without departing from the spirit and scope of the invention or sacrificing all of its material advantages, the examples hereinbefore described merely being preferred or exemplary embodiments of the invention.
Number | Date | Country | Kind |
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97100303 | Jan 2008 | TW | national |