The current disclosure is regarding an electrical slip ring assembly that transmit signals, data, and power across rotary platforms, especially for high frequency applications. The high frequency slip ring assembly with through bore may include a first stage slip ring, a second stage slip ring, a gear assembly, and an internal cable assembly. Rings may have an angled notch on a circumference to break said rings and have the same diameter. The first stage slip ring and second stage slip ring may be connected in series sequence, i.e., the stator in first stage slip ring is mechanically connected with the rotor in second stage slip ring. The internal cable assembly electrically connects the brush assembly in first stage slip ring with the ring assembly in said second stage slip ring in each channel respectively.

The current disclosure is regarding an electrical slip ring assembly that transmit signals, data, and power across rotary platforms, especially for high frequency applications. The high frequency slip ring assembly with through bore may include a first stage slip ring, a second stage slip ring, a gear assembly, and an internal cable assembly. Rings may have an angled notch on a circumference to break said rings and have the same diameter. The first stage slip ring and second stage slip ring may be connected in series sequence, i.e., the stator in first stage slip ring is mechanically connected with the rotor in second stage slip ring. The internal cable assembly electrically connects the brush assembly in first stage slip ring with the ring assembly in said second stage slip ring in each channel respectively.

A transmitter is configured to generate a signal carrying data. A signal splitter is configured to generate multiple copies of the signal. A slip ring includes first and second portions, one configured to rotate relative to the other. The slip ring also includes a first interface associated with the first portion and configured to receive the multiple copies of the signal. The slip ring further includes a second interface associated with the second portion. In addition, the slip ring includes multiple electrical pathways electrically coupling the first and second interfaces, where at least some of the electrical pathways are configured to transport the multiple copies of the signal from the first interface to the second interface. A signal combiner is configured to receive the multiple copies of the signal from the second interface and to generate a recovered signal. A receiver is configured to recover the data from the recovered signal.

A transmitter is configured to generate a signal carrying data. A signal splitter is configured to generate multiple copies of the signal. A slip ring includes first and second portions, one configured to rotate relative to the other. The slip ring also includes a first interface associated with the first portion and configured to receive the multiple copies of the signal. The slip ring further includes a second interface associated with the second portion. In addition, the slip ring includes multiple electrical pathways electrically coupling the first and second interfaces, where at least some of the electrical pathways are configured to transport the multiple copies of the signal from the first interface to the second interface. A signal combiner is configured to receive the multiple copies of the signal from the second interface and to generate a recovered signal. A receiver is configured to recover the data from the recovered signal.

The current disclosure is regarding an electrical slip ring assembly that transmit signals, data, and power across rotary platforms, especially for high frequency applications. The high frequency slip ring assembly with through bore may include a first stage slip ring, a second stage slip ring, a gear assembly, and an internal cable assembly. Rings may have an angled notch on a circumference to break said rings and have the same diameter. The first stage slip ring and second stage slip ring may be connected in series sequence, i.e., the stator in first stage slip ring is mechanically connected with the rotor in second stage slip ring. The internal cable assembly electrically connects the brush assembly in first stage slip ring with the ring assembly in said second stage slip ring in each channel respectively.

A slip ring includes a first dielectric carrier body and a second dielectric carrier body, each carrier body having at least one shoulder extending circumferentially along a circle line. In addition, the slip ring includes conductor elements, which have an annular and closed configuration with respect to an axis, at least one conductor element, which is fixed in place on the shoulder of the first dielectric carrier body, and at least one conductor element, which is fixed in place on the shoulder of the second dielectric carrier body. The first dielectric carrier body is arranged at an offset from the second dielectric carrier body in the direction of the axis, so that the shoulder having the at least one conductor element of the first dielectric carrier body and the shoulder having the at least one conductor element of the second dielectric carrier body are located axially across from each other.

A slip ring includes a first dielectric carrier body and a second dielectric carrier body, each carrier body having at least one shoulder extending circumferentially along a circle line. In addition, the slip ring includes conductor elements, which have an annular and closed configuration with respect to an axis, at least one conductor element, which is fixed in place on the shoulder of the first dielectric carrier body, and at least one conductor element, which is fixed in place on the shoulder of the second dielectric carrier body. The first dielectric carrier body is arranged at an offset from the second dielectric carrier body in the direction of the axis, so that the shoulder having the at least one conductor element of the first dielectric carrier body and the shoulder having the at least one conductor element of the second dielectric carrier body are located axially across from each other.

A slip ring assembly is usable with a surgical shaft assembly. The slip ring assembly includes a first connector flange comprising a conductor. The slip ring assembly further includes a second connector flange comprising a conductive element in contact with the conductor, wherein the second connector flange is rotatable relative to the first connector flange. In addition, the slip ring assembly also includes a support member, wherein the second connector flange is sandwiched between the first connector flange and the support member, and wherein the support member is configured to apply a load onto the second connector flange to maintain the contact between the conductor and the conductive element.

A slip ring assembly is usable with a surgical shaft assembly. The slip ring assembly includes a first connector flange comprising a conductor. The slip ring assembly further includes a second connector flange comprising a conductive element in contact with the conductor, wherein the second connector flange is rotatable relative to the first connector flange. In addition, the slip ring assembly also includes a support member, wherein the second connector flange is sandwiched between the first connector flange and the support member, and wherein the support member is configured to apply a load onto the second connector flange to maintain the contact between the conductor and the conductive element.

The present disclosure relates to a conductive slip ring for logging while drilling (LWD) instrument. The present disclosure utilizes a mechanical conductive slip ring to solve the problems of transmission of electric power and signals between two structures that have relative rotation, and the conductive slip ring has a simple structure, doesn't involve any complex circuit, and has low cost and high reliability. With the conductive slip ring in the present disclosure, there is no power transmission efficiency problem or signal transmission error rate problem. The conductive slip ring has high temperature-resistant, pressure-proof, and vibration-roof abilities, and can be applied widely.