A portable dehumidifier includes a cabinet and a pivoting handle. The pivoting handle is configured to pivot from a stored position to an engaged position. The pivoting handle includes a cross member, two extension members, and a cam arm. The cam arm is coupled to one of the extension members at an end of the extension member that is opposite the cross member. The cam arm includes a spring arm configured to engage with a locking pin coupled to the cabinet, a clearance hole configured to permit the cam arm to clear the locking pin when the pivoting handle is in the stored position, an aperture configured to permit a pivot pin to secure the cam arm to the cabinet, and a compression gap adjacent to the spring arm. The compression gap is configured to permit the spring arm to provide resistance to the pivoting handle during pivoting.

A method, for controlling a fan of a dehumidifier includes performing a first step of obtaining an ambient temperature, an exhaust temperature, and a delta temperature that is a difference between the ambient temperature and the exhaust temperature. The method further include determining, after performing the first step, whether the delta temperature is within a delta temperature range. If the delta temperature is within the delta temperature range, the method proceeds back to the first step. If the delta temperature is not within the delta temperature range, the method performs a second step of determining an adjusted fan speed using the delta temperature. The method further includes performing, after performing the second step, a third step of setting the fan speed to the determined adjusted fan speed.

A portable dehumidifier includes a cabinet, a fan, a dehumidification system, and a compressor. The cabinet includes a front side and a back side opposite the front side, an airflow inlet located on a first side of the cabinet, and an airflow outlet located on a second side of the cabinet that is opposite the first side. The dehumidification system includes a secondary evaporator located proximate to the airflow inlet, a primary condenser located proximate to the airflow outlet, a primary evaporator located adjacent to the secondary evaporator, a secondary condenser located between the primary evaporator and the primary condenser, and a compressor. The fan is configured to generate an airflow that flows into the cabinet through the airflow inlet and out of the cabinet through the airflow outlet. The airflow flows through the dehumidification system in order to provide dehumidification to the airflow.

An isolated human work platform for stabilized positioning of collaborative robotics. A base platform is provided, and a work platform is positioned above the base platform for supporting one or more humans. One or more robots are supported on the base platform independently of the work platform, so that movement of the work platform does not affect the robots' positions. The work platform is isolated from the robots for stabilized positioning of the robots, so that the base platform and work platform together provide a collaborative workspace for the robots and the humans.

An isolated human work platform for stabilized positioning of collaborative robotics. A base platform is provided, and a work platform is positioned above the base platform for supporting one or more humans. One or more robots are supported on the base platform independently of the work platform, so that movement of the work platform does not affect the robots' positions. The work platform is isolated from the robots for stabilized positioning of the robots, so that the base platform and work platform together provide a collaborative workspace for the robots and the humans.

A system a first mobile body configured to support a turbine engine and an auxiliary skid communicatively and fluidly coupled to the turbine engine. The auxiliary skid includes one or more interconnects configured to support a turbine engine component. The system also includes a second mobile body configured to support a generator. The first and second mobile bodies are configured to align a removable coupling between the turbine engine and the generator.

A system a first mobile body configured to support a turbine engine and an auxiliary skid communicatively and fluidly coupled to the turbine engine. The auxiliary skid includes one or more interconnects configured to support a turbine engine component. The system also includes a second mobile body configured to support a generator. The first and second mobile bodies are configured to align a removable coupling between the turbine engine and the generator.

An equipment stand having a main support beam with opposing first and second ends; a rotating hub and spindle assembly attachable at its lower end to the main support beam; a first platform mounted to the upper end of the rotating hub and spindle assembly; a support leg attached perpendicularly to the first end of the main support beam; a vehicle hitch connection post extending perpendicularly from the support leg and colinearly with the main support beam; lifting means hingedly connected to the second end of the main support beam; and telescopic tubing connecting the lifting means to a wheel and axle assembly. The equipment stand may be used for storage, transport or operation of various construction trades equipment including pipe and bolt threaders, generators, coiling frames, saws, and other construction trades equipment.

An equipment stand having a main support beam with opposing first and second ends; a rotating hub and spindle assembly attachable at its lower end to the main support beam; a first platform mounted to the upper end of the rotating hub and spindle assembly; a support leg attached perpendicularly to the first end of the main support beam; a vehicle hitch connection post extending perpendicularly from the support leg and colinearly with the main support beam; lifting means hingedly connected to the second end of the main support beam; and telescopic tubing connecting the lifting means to a wheel and axle assembly. The equipment stand may be used for storage, transport or operation of various construction trades equipment including pipe and bolt threaders, generators, coiling frames, saws, and other construction trades equipment.

A vibration isolator mount system includes a base rail; a mounting rail coupled to a piece of equipment, the mounting rail including a mounting bracket; and a vibration isolator. The vibration isolator includes an isolator body. The vibration isolator includes a foundation pin, the foundation pin extending downward from the isolator body and through a base hole formed in the base rail. The foundation pin includes a base plate and a foundation elastomeric body. The foundation elastomeric body may be positioned between the isolator body and the base plate. The vibration isolator includes a stud. The stud may extend upward from the isolator body and through a stud hole formed in the mounting bracket.