A peristaltic pump head includes a housing assembly adapted for mounting to a drive mechanism, a roller assembly arranged with the housing assembly and a flexible conduit extending through the housing assembly and engageable by the roller assembly to impel fluid therethrough. The roller assembly and the flexible conduit are removable from the housing assembly without disconnecting the entire housing assembly from the drive mechanism. The roller assembly can include an axially extending drive shaft, a roller control body fixedly mounted to the drive shaft, at least a first end plate rotatably mounted about the drive shaft, and at least a first roller arm pivotably mounted to the first end plate. The flexible conduit can include a length of hollow tubing made of an elastomeric material, and at least one overmolded end fitting made of a rigid polymeric material and fused to an end of the hollow tubing.

A peristaltic pump apparatus for a medical device has a housing, a motor, a first peristaltic pump head, a second peristaltic pump head, a first clutch assembly, and a second clutch assembly. The motor is directly connected to the housing and has a rotatable drive shaft. Each of the first peristaltic pump head and the second peristaltic pump head is coupled to the rotatable drive shaft. The first clutch assembly has a first rotor fixedly connected to the rotatable drive shaft and a first stator directly connected to the housing. The first clutch assembly is configured to selectively electromagnetically couple the first rotor to the first peristaltic pump head. The second clutch assembly has a second rotor fixedly connected to the rotatable drive shaft and a second stator directly connected to the housing. The second clutch assembly selectively electromagnetically couples the second rotor to the second peristaltic pump head.

An injection system is proposed which comprises at least one supply station for supplying a medical fluid to be injected into a patient's vasculature, a pressurizing unit comprising a motor for pressurizing said medical fluid, a delivery arrangement in fluid communication with the at least one supply station and a patient set assembly in fluid communication with the delivery arrangement. The patient set assembly comprises a delivery tube for delivering the pressurized fluid to the patient and a peristaltic pump component comprising a casing which includes an inlet port and an exit port, the inlet port being in fluid communication with the delivery arrangement and the exit port being in fluid communication with the delivery tube. According to an embodiment of the present invention, in proximity of the inlet port, the casing of the peristaltic pump component has a substantially U-shaped configuration. The present invention also relates to a patient set assembly and to a peristaltic pump component.

Provided is a tube pump system in which a first insertion groove extending along a first axial direction is formed in a first accommodating portion of a first tube pump, the first tube pump includes a first tube holding member that holds a first tube in the first insertion groove, a second insertion groove extending along a second axial direction is formed in a second accommodating portion of a second tube pump, the second tube pump includes a second tube holding member that holds the second tube in the second insertion groove, the shape of the first insertion groove is different from the shape of the second insertion groove, the first tube holding member has a shape corresponding to the first insertion groove, and the second tube holding member has a shape corresponding to the second insertion groove.

A peristaltic pump system includes tubing with first and second tube collars. The system also includes a rotary peristaltic pump with a tube channel having first and second ends, a first tube guide disposed at the first end and a second tube guide disposed at the second end. The first and second tube guides each include a passage with an inner diameter that is larger than the outer diameter of the tubing. The first tube guide has an unrestricted shoulder configured to abut the first tube collar in an installation state, and the second tube guide has an unrestricted shoulder configured to abut the second tube collar in the installation state. The first tube guide passage is disposed between its shoulder and the first end of the tube channel, while the second tube guide passage is disposed between its shoulder and the second end of the tube channel.

A peristaltic pump is disclosed that includes a plunger, a spring, an actuator, a position sensor, and a processor. The plunger actuates toward and away from a tube. The spring biases the plunger toward the tube. The actuator actuates the plunger away from the tube and mechanically engages and disengages from the plunger. The position sensor senses a position of the plunger. The processor receives the sensed position of the plunger and estimates fluid flow within the tube using a first position of the plunger when the actuator is engaged with the plunger and a second position of the plunger when the actuator is disengaged from the plunger.

The present invention involves a rotary peristaltic pump and associated method employing the relaxation of pressure on flexible tubing between the rotor and stator of the pump to restore the rotor to a start angle while a valve on the output of the pump is closed to avoid progress of fluid through the system. Three different implementations of the pump and method are presented including reciprocating the stator, reciprocating the rotor, and retracting the idler rollers of the rotor into the rotor to relieve the pressure on the flexible tubing. A controller ensures the appropriate switching and timing of the valve and rotor of the pump. The pump and associated method are directed to the precision dispensing of pharmaceutical fluids into containers, including containers held in container nests.

A peristaltic pump has an arcuate raceway wife a partially concave inner surface extending through an arc of at least one hundred eighty degrees (180°). The are defines a midpoint, and a rotor faces the inner surface of the raceway and is both rotatable relative to the raceway and transitionally movable relative to the raceway between a pump position, wherein the rotor is spaced from the midpoint a first distance, and a tube load position, wherein the rotor is spaced from the midpoint a second distance greater than the first distance. A rotor motor is coupled to the rotor to rotate the rotor and rollers arranged on the rotor to contact tubing disposed between the rotor and the raceway when the rotor is in the pump position. A loading motor moves the rotor toward and away from the raceway.

A peristaltic pump includes a motor, a rotor coupled to the motor, a housing in which the rotor is arranged, and an opening and closing mechanism. The mechanism includes a tube pressuring portion, a slider, and a pivotable cover coupled to the housing and the slider and the mechanism is connected to the slider and the tube pressuring portion such that a tube engaging surface of the tube pressuring portion slides towards and away from the rotor upon closing and opening of the pivotable cover. The opening and closing mechanism further includes a slider moving element attached to the slider, the pivotable cover including a rotating shaft having an extension configured to engage the slider moving element for moving the slider and also the tube pressuring portion away and towards a top of the housing in response to a respective opening and closing of the pivotable cover.

A pump system for an atomizer nozzle system having at least two atomizer nozzles, in particular for an electrohydrodynamic atomizer as well as a method for operating an electrohydrodynamic atomizer, wherein the pump system comprises at least one hose assembly as well as at least one pump rotor (7) and at least one rolling body (6) for forming a rolling region of a peristaltic pump, wherein the hose assembly comprises at least the same number of hose channels as the number of atomizer nozzles, and in that each hose channel is assigned to an atomizer nozzle and connects it to the rolling region.