An automatic lubricator for lubricating an object is provided. The lubricator includes a housing with a coupling section configured to couple with a lubricant container containing a lubricant, wherein the lubricant container comprises a rotatable shaft with a piston to dispense the lubricant from an output of the lubricant container. The lubricator further includes an electric motor configured to drive the rotatable shaft of the lubricant container during at least one lubrication action, such that at least a part of the lubricant is dispensable from the lubricant container during the at least one lubrication action. The lubricator further includes at least one sensor arranged within the housing and configured to provide a sensor signal indicative of a distance between the at least one sensor and the piston of the lubricant container, and a control circuitry configured to determine, based on the sensor signal of the at least one sensor, at least one lubrication parameter indicative of the at least one lubrication action

A fan housing includes a housing body for accommodating fan components and an outer casing which surrounds the housing body in circumferential direction. The housing body has at least two webs extending in a circumferential direction on the radial outer side. The outer casing has at least two ribs extending in the circumferential direction on the radial inner side. The ribs, in the assembled state, between the housing body and the outer casing, form a channel circulating in the circumferential direction for receiving and holding a heating band. The outer casing has at least one guiding rib directed in the radial direction toward a housing body as well as into the channel and extending in the circumferential direction.

A fan housing includes a housing body for accommodating fan components and an outer casing which surrounds the housing body in circumferential direction. The housing body has at least two webs extending in a circumferential direction on the radial outer side. The outer casing has at least two ribs extending in the circumferential direction on the radial inner side. The ribs, in the assembled state, between the housing body and the outer casing, form a channel circulating in the circumferential direction for receiving and holding a heating band. The outer casing has at least one guiding rib directed in the radial direction toward a housing body as well as into the channel and extending in the circumferential direction.

The lubricant level within a reservoir is difficult to monitor, leading to the reservoir being refilled more often than necessary to ensure that the reservoir always contains lubricant. A lubricant level sensing system is connected to and monitors various aspects of the pump assembly that draws lubricant from the reservoir. The pump assembly displaces a known volume of lubricant with each pump stroke. A lubricant-level estimator calculates an estimated lubricant level remaining in the reservoir based on a stroke-count value as sensed from the pump assembly and on a reference value stored in a memory. The estimated lubricant level provides the lubricant remaining and the rate of usage such that maintenance can be scheduled ahead of time to prevent the reservoir running dry.

The lubricant level within a reservoir is difficult to monitor, leading to the reservoir being refilled more often than necessary to ensure that the reservoir always contains lubricant. A lubricant level sensing system is connected to and monitors various aspects of the pump assembly that draws lubricant from the reservoir. The pump assembly displaces a known volume of lubricant with each pump stroke. A lubricant-level estimator calculates an estimated lubricant level remaining in the reservoir based on a stroke-count value as sensed from the pump assembly and on a reference value stored in a memory. The estimated lubricant level provides the lubricant remaining and the rate of usage such that maintenance can be scheduled ahead of time to prevent the reservoir running dry.

There is provided a bearing lubrication application control system which comprises a digital controller device operably coupled to a lubrication meter and a computer readable medium reader. As such, during lubrication application, the digital controller device is configured for reading bearing data from bearing computer readable media associated with each bearing and also recording an applied lubrication volume for each of the bearings. As such, for a subsequent lubrication application, the digital controller device is configured for calculating a dynamic lubrication schedule for each of the bearings wherein the schedule comprises at least an appropriate lubrication volume to be applied calculated at least according to the stored apply lubrication volume for each of the plurality of bearings.

There is provided a bearing lubrication application control system which comprises a digital controller device operably coupled to a lubrication meter and a computer readable medium reader. As such, during lubrication application, the digital controller device is configured for reading bearing data from bearing computer readable media associated with each bearing and also recording an applied lubrication volume for each of the bearings. As such, for a subsequent lubrication application, the digital controller device is configured for calculating a dynamic lubrication schedule for each of the bearings wherein the schedule comprises at least an appropriate lubrication volume to be applied calculated at least according to the stored apply lubrication volume for each of the plurality of bearings.

A lubricant distribution system includes at least one lubricant pump, at least one metering device for distributing metered amounts of lubricant to consumption points, a sensor unit including at least one sensor element configured to detect at least one operating parameter of the metering device, and at least one programmable control unit configured to control the lubricant pump based on the detected operating parameter.

A lubricant distribution system includes at least one lubricant pump, at least one metering device for distributing metered amounts of lubricant to consumption points, a sensor unit including at least one sensor element configured to detect at least one operating parameter of the metering device, and at least one programmable control unit configured to control the lubricant pump based on the detected operating parameter.

An automated zipper manifold with remotely and independently controlled and monitored valves, wherein second pressure transducers are positioned on the zipper manifold and are configured to determine a flow analysis across the valve.