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    • 3. 发明授权
    • System and method for controlling an ultraviolet air treatment device for air conditioner cooling coil irradiation applications
    • 用于控制空调冷却盘管照射应用的紫外线空气处理装置的系统和方法
    • US06438971B1
    • 2002-08-27
    • US09995049
    • 2001-11-26
    • Tracy L. LentzTimothy J. Kensok
    • Tracy L. LentzTimothy J. Kensok
    • F24F316
    • F24F3/166F24F2003/1667
    • A method of controlling an ultraviolet air treatment device including an ultraviolet lamp positioned to irradiate an air conditioner cooling coil. A controller is connected to the ultraviolet air treatment device to dictate activation and deactivation of the ultraviolet lamp. A first control sequence is performed to automatically cycle the ultraviolet lamp between a powered on condition for a first predetermined time period and a powered off condition for a second predetermined time period. In one preferred embodiment, the method further includes monitoring an operational mode of the air conditioner. A transition routine is initiated upon determining that the operational mode has switched from cooling to non-cooling, and the ultraviolet lamp is controlled in accordance with a second control sequence if the air conditioner remains in the non-cooling mode throughout an entirety of the transition routine.
    • 一种控制紫外线空气处理装置的方法,所述紫外线空气处理装置包括定位成照射空调冷却盘管的紫外灯。 控制器连接到紫外线空气处理装置以指示紫外线灯的激活和去激活。 执行第一控制顺序以在第一预定时间段的通电状态和第二预定时间段的断电条件之间自动循环紫外灯。 在一个优选实施例中,该方法还包括监视空调器的操作模式。 在确定操作模式已经从冷却切换到非冷却时开始转换程序,并且如果空调器在整个转换过程中保持非冷却模式,则根据第二控制顺序来控制紫外线灯 常规。
    • 7. 发明授权
    • Dehumidifier using non-rotating desiccant material
    • 除湿机采用非旋转干燥剂材料
    • US06364942B1
    • 2002-04-02
    • US09519870
    • 2000-03-06
    • Steven M. FelberTimothy J. KensokTimothy J. Smith
    • Steven M. FelberTimothy J. KensokTimothy J. Smith
    • B01D5304
    • F24F3/1411B01D53/261F24F2003/144
    • A dehumidification system for dehumidifying a conditioned space. The system is comprised of a motionless desiccant block for dehumidifying air within the conditioned space. The system is configured to operate in one of two modes. In a first dehumidifying mode the system draws air from the conditioned space, dehumidifies the air, and returns the air to the conditioned space. In a second regeneration mode the system draws air from outside the conditioned space, heats the air, passes the heated air through the desiccant to dry the desiccant, and expels the air back outside the conditioned space. The system is configured with pivoting dampers to select air source and air destination for the two modes of the system. The system includes blowers in order to motivate the flow of air and a regenerative heater for use during regeneration mode. By utilizing a motionless desiccant block the system avoids the expense and maintenance of desiccant wheels and wheel motors.
    • 一个除湿系统,用于除空调空间。 该系统由静止干燥剂块组成,用于对空调空间内的空气进行除湿。 该系统配置为以两种模式之一运行。 在第一除湿模式中,系统从调节空间抽取空气,对空气进行除湿,并将空气返回到调节空间。 在第二再生模式中,系统从调节空间外部吸入空气,加热空气,将加热的空气通过干燥剂干燥干燥剂,并将空气排出空调空间。 该系统配置有枢转阻尼器,用于为系统的两种模式选择空气源和空气目的地。 该系统包括鼓风机,以便激发空气流和再生模式下使用的再生加热器。 通过使用不动干燥剂块,系统避免了干燥剂轮和轮式电机的费用和维护。
    • 9. 发明授权
    • Rotary cam load positioning apparatus
    • 旋转凸轮负载定位装置
    • US4934271A
    • 1990-06-19
    • US386747
    • 1989-07-31
    • Timothy J. KensokPeter H. Van Sloun
    • Timothy J. KensokPeter H. Van Sloun
    • F16M11/12F42B23/24
    • F16M11/18F16M11/126F42B23/24
    • A rotary cam load positioning apparatus has a base, a bottom cam rotatably mounted on the base, and a top cam rotatably mounted on the bottom cam. The rotary cams have cylindrical wedge-shaped configurations with respective upper and lower surfaces disposed in inclined relation to one another. Thus, rotation of the top cam relative to the bottom cam will produce a change in the elevation position of a load supported on the upper surface of the top cam relative to the base, whereas rotation of both top and bottom cams together will produce a change in the azimuth position of the load supported on the upper surface of the top cam relative to the base.
    • 旋转凸轮负载定位装置具有基座,可旋转地安装在基座上的底部凸轮和可旋转地安装在底部凸轮上的顶部凸轮。 旋转凸轮具有圆柱形楔形构造,其相应的上表面和下表面彼此倾斜地设置。 因此,顶部凸轮相对于底部凸轮的旋转将导致支撑在顶部凸轮的上表面上的负载相对于基座的升高位置的变化,而顶部凸轮和底部凸轮的旋转将一起产生变化 在负载在顶部凸轮的上表面上的负载相对于基座的方位位置。