A unitized valve body for use in an automatic transmission includes a plurality of first hydraulic passages, a second hydraulic passage and a plurality of orifices. The second hydraulic passage extending through the unitized valve body and configured to be in fluid communication with a plurality of valve bores. Each orifice disposed within the unitized valve body and fluidly connecting the second hydraulic passage to a respective first hydraulic passage of the plurality of first hydraulic passages.

A unitized valve body for use in an automatic transmission includes a plurality of first hydraulic passages, a second hydraulic passage and a plurality of orifices. The second hydraulic passage extending through the unitized valve body and configured to be in fluid communication with a plurality of valve bores. Each orifice disposed within the unitized valve body and fluidly connecting the second hydraulic passage to a respective first hydraulic passage of the plurality of first hydraulic passages.

A unitized valve body for use in an automatic transmission includes a valve bore and an annulus. The valve bore is configured to receive a valve. The annulus is in fluid communication with the valve bore. The annulus defines an outer portion having an outer diameter and an innermost portion located at an interface between the valve bore and the valve. The outer portion having a first axial length and the innermost portion having a second axial length. The first axial length is greater than the second axial length.

A unitized valve body for use in an automatic transmission includes a valve bore and an annulus. The valve bore is configured to receive a valve. The annulus is in fluid communication with the valve bore. The annulus defines an outer portion having an outer diameter and an innermost portion located at an interface between the valve bore and the valve. The outer portion having a first axial length and the innermost portion having a second axial length. The first axial length is greater than the second axial length.

A fluid supply interface includes a line component having a first coupling formation for the temporary coupling of a first fluid channel, a second coupling formation for the temporary coupling of a second fluid channel, and a third coupling formation for the temporary or permanent coupling of a third fluid channel, each of said coupling formations being penetrated by a fluid line section, wherein in the line component, a fluid line assembly is formed, by means of which each fluid line section of the first, second and third coupling formations is or can be connected to each fluid line section of the other two coupling formations for the purpose of fluid transport.

Provided is a multi-port gas flow rate control apparatus. The multi-port gas flow rate control apparatus includes a gas supply chamber configured to supply a measurement gas input through one gas inflow channel while allowing the measurement gas to diverge into a plurality of flows, a plurality of gas divergence flow channels each having one side connected to the gas supply chamber and configured to transfer the measurement gas flowing through the gas supply chamber to a plurality of gas sensors, respectively, and a gas measurement chamber configured to accommodate the plurality of gas sensors, including the plurality of gas divergence flow channels configured to connect to the gas supply chamber to the plurality of gas sensors to transfer a gas outflow diverging through the gas supply chamber to the plurality of accommodated gas sensors, and configured to discharge the gas outflow sensed by the plurality of gas sensors.

Provided is a multi-port gas flow rate control apparatus. The multi-port gas flow rate control apparatus includes a gas supply chamber configured to supply a measurement gas input through one gas inflow channel while allowing the measurement gas to diverge into a plurality of flows, a plurality of gas divergence flow channels each having one side connected to the gas supply chamber and configured to transfer the measurement gas flowing through the gas supply chamber to a plurality of gas sensors, respectively, and a gas measurement chamber configured to accommodate the plurality of gas sensors, including the plurality of gas divergence flow channels configured to connect to the gas supply chamber to the plurality of gas sensors to transfer a gas outflow diverging through the gas supply chamber to the plurality of accommodated gas sensors, and configured to discharge the gas outflow sensed by the plurality of gas sensors.

A manifold has a fluid inlet, a plurality of fluid outlets, a movable conduit member, a first drive mechanism, and a control module in which the conduit member has a fluid path therethrough, in which the fluid inlet is fluidly connected to a first end of the fluid path, in which the conduit member is mounted for movement on a support member, and in which the first drive mechanism is configured to move the conduit member on the support member to selectively associate a second end of the fluid path with one of the plurality of fluid outlets according to commands issued by the control module.

A manifold has a fluid inlet, a plurality of fluid outlets, a movable conduit member, a first drive mechanism, and a control module in which the conduit member has a fluid path therethrough, in which the fluid inlet is fluidly connected to a first end of the fluid path, in which the conduit member is mounted for movement on a support member, and in which the first drive mechanism is configured to move the conduit member on the support member to selectively associate a second end of the fluid path with one of the plurality of fluid outlets according to commands issued by the control module.

Exemplary spatial genomics systems may include a flow cell and a fluid manifold. The flow cell may define an open interior, a fluid inlet to a first end of the open interior, and a fluid outlet to a second end of the open interior opposite the first end. The fluid manifold may include a body defining a plurality of fluid inlet lumens, a fluid outlet lumen, and a fluid waste lumen. Each of the plurality of fluid inlet lumens may be fluidly coupled with the fluid outlet lumen. The fluid outlet lumen may be fluidly coupled with the flow cell. The fluid manifold may include a plurality of fluid switches. Each of the plurality of fluid switches may be fluidly coupled with a respective one of the plurality of fluid inlet lumens. The fluid waste lumen may be fluidly coupled with the fluid outlet of the flow cell.