A vacuum pump system includes a first vacuum pump and a second vacuum pump connected to an exhaust port of the first vacuum pump. The second vacuum pump has a pump portion and a trap portion. The pump portion has a rotor. The trap portion is configured such that a reaction product generated from gas guided to an internal space from the exhaust port of the first vacuum pump by suction by the pump portion is accumulated thereon.

A vacuum pump system comprises: a vacuum pump including a suction port, an exhaust port, and a pressure detection section configured to detect a gas pressure in a gas flow path through which gas sucked through the suction port flows to the exhaust port; and an arithmetic device configured to perform arithmetic processing for a state of a deposition substance in the gas flow path based on the gas pressure detected by the pressure detection section.

A vacuum pump includes a linked-type thread-groove spacer which is a structure for linking a Siegbahn pump portion and a thread-groove pump portion, and when an outlet position of a thread groove which is an exhaust channel portion of this linked-type thread-groove spacer is in a vicinity of the stator portion (stator bolt) of the stator column, conductance of the exhaust channel is lowered. Thus, phases in a circumferential direction of installation positions of a thread ridge of the linked-type thread-groove spacer and the stator portion of the stator column are aligned as much as possible. In other words, the thread groove of the linked-type thread-groove spacer which is the exhaust channel is provided between the installation positions of the stator portions in the circumferential direction of the stator column so that lowering of the conductance of the exhaust channel is suppressed.

A drag pump for pumping fluid from an inlet to an outlet includes a stator and a rotor. One of the stator or rotor includes a disc having a plurality of channels each of the channels extending from an inlet portion of the disc at or close to an inlet edge towards an outlet portion at or close to an outlet edge. The plurality of channels each has walls for guiding fluid flow from the inlet edge to the outlet edge in response to relative motion between the stator and the rotor. The disc further includes a plurality of protrusions extending from the channels, each of the protrusions being arranged to divide a channel at the inlet or the outlet end of the channel, into sub-channels that extend for a portion of a length of the channel and do not extend for a whole length of the channel.

A vacuum pump includes a linked-type thread-groove spacer which is a structure for linking a Siegbahn pump portion and a thread-groove pump portion, and when an outlet position of a thread groove which is an exhaust channel portion of this linked-type thread-groove spacer is in a vicinity of the stator portion (stator bolt) of the stator column, conductance of the exhaust channel is lowered. Thus, phases in a circumferential direction of installation positions of a thread ridge of the linked-type thread-groove spacer and the stator portion of the stator column are aligned as much as possible. In other words, the thread groove of the linked-type thread-groove spacer which is the exhaust channel is provided between the installation positions of the stator portions in the circumferential direction of the stator column so that lowering of the conductance of the exhaust channel is suppressed.

Provided is a pump monitoring device diagnosing an accumulation of a reaction product in a vacuum pump. The pump monitoring device includes an acquisition unit configured to acquire data representing pump state of the vacuum pump, a statistical value calculation unit configured to calculate a statistical value representing a width of data distribution per predetermined time period, based on the data acquired by the acquisition unit, and a diagnosis unit configured to output diagnostic information of the vacuum pump about an amount of the accumulation of the reaction product, based on the statistical value.

A vacuum pump comprises: a rotor having multiple stages of rotor blades and a rotor cylindrical portion; a stator having multiple stages of stator blades and a stator cylindrical portion; a base housing the rotor and the stator; and a cover member configured to cover an inner wall portion of the base forming an internal space positioned on a gas-discharge downstream side with respect to gas-discharge-downstream-side end portions of the rotor cylindrical portion and the stator cylindrical portion. An inner peripheral side end of the cover member extends from the internal space to a position overlapping with an inner peripheral surface of the rotor cylindrical portion.

A vacuum pump comprises: a rotor cylindrical portion; a motor configured to rotate the rotor cylindrical portion; a stator cylindrical portion, the rotor cylindrical portion and the stator cylindrical portion together forming a screw groove pump; a base housing the rotor cylindrical portion and the stator cylindrical portion; a heater configured to heat the base or the stator cylindrical portion; a cooling device attached to the base; and a cover member arranged at an outer peripheral side of the stator cylindrical portion and an outer peripheral side of the base, covering the base through an air insulating layer, and contacting the cooling device.

Decane (C10H22) is sprayed as a mist from spray nozzles toward a rotor blade via a supply pipe and communication passages. Since decane has a boiling point of 174° C. at atmospheric pressure, the decane is a liquid at normal temperature and normal pressure. On the other hand, the pressure inside a turbomolecular pump is in a substantially vacuum state of about 100 Pa, and the boiling point of decane at this pressure is 14° C. Thus, although the pressure is high and the decane is in a liquid state until the decane is sprayed, when the decane adheres to surfaces of the rotor blades and the temperature of the decane rises, the decane vaporizes. At this moment, since the amount of heat of the rotor blades is consumed as heat of vaporization, the rotor blades can be cooled.

A drag pump for pumping gas and a set of vacuum pumps including the drag pump are disclosed. The drag pump comprises: a rotor configured to rotate within a stator component and to drive a gas to be pumped from a gas inlet to a gas outlet; magnetic bearings for rotatably mounting the rotor within the pump; wherein at least a portion of the rotor and stator component configured to contact the gas to be pumped are configured for operation at temperatures above 130° C.