The present invention relates to a power source integrated vacuum pump.
A vacuum pump used for vacuum pumping of an external device such as a semiconductor manufacturing device includes a pump main body and a power source device configured to control the pump main body. A power source integrated vacuum pump configured such that a pump main body and a power source device are integrated together has been known (see, e.g., JP 2014-148977). In this pump, a cooling jacket configured such that coolant water circulates in the cooling jacket is provided between the pump main body and the power source device. A surface of the cooling jacket functions as a cooling surface. Of substrates provided at the power source device, a substrate on which an intensive-cooling requiring component requiring intensive cooling is mounted is fixed such that a substrate back surface contacts the surface of the cooling jacket.
Normally, the power source device has a semi-closed structure, and a dew point temperature in the power source device is the same as that outside the power source device, i.e., the temperature of external air. In the above-described power source integrated vacuum pump, when an exposed region to which no substrate is fixed is present at the cooling surface of the cooling jacket, the exposed region might reach a lower temperature than the dew point temperature, leading to dew condensation.
A power source integrated vacuum pump configured such that a pump main body and a pump power source device are integrated together, comprises: a substrate which is provided at the pump power source device and on which an electronic component is mounted; a cooling device having a cooling surface fixed in contact with the substrate; and a heat insulating member having a smaller coefficient of thermal conductivity than that of a material forming the cooling surface and covering a cooling surface region to which the substrate is not fixed.
The cooling device is a cooling jacket configured such that refrigerant circulates in the cooling jacket and arranged between the pump main body and the pump power source device, and the cooling surface is formed at a pump power source device side surface of the cooling jacket.
The heat insulating member is detachably provided on the cooling surface.
The cooling device is configured such that an optional circuit substrate can be fixed on the cooling surface region instead of detached heat insulating member.
The optional circuit substrate is an optional circuit substrate for communication or an optional substrate for an AC/DC circuit for three-system temperature adjustment.
The heat insulating member is made of a resin material, and the cooling surface is made of a metal material.
Percentage of total area where the substrate and the heat insulating member are fixed to the cooling surface relative to total area of the cooling surface is larger than 80.
According to the present invention, dew condensation on the cooling surface can be prevented.
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
In the pump unit 20, a shaft 3 attached to a rotor 2 is non-contact supported by magnetic bearings 51A, 51B, 52 provided at a pump base 4. A levitation position of the shaft 3 is detected by radial displacement sensors 71A, 71B and an axial displacement sensor 72 provided at the pump base 4. Note that in a state in which the magnetic bearings are not in operation, the shaft 3 is supported by mechanical bearings 27, 28.
A circular rotor disc 41 is provided at a lower end of the shaft 3, and electromagnets of the magnetic bearing 52 are provided to sandwich the rotor disc 41 in an upper-to-lower direction through a clearance. The rotor disc 41 is attracted by the magnetic bearing 52 such that the shaft 3 is levitated in an axial direction. The rotor disc 41 is fixed to a lower end portion of the shaft 3 with a nut member 42.
The rotor 2 is provided with multiple rotor blades 8 in a rotation axis direction. Each stationary blade 9 is arranged between adjacent ones of the rotor blades 8 arranged in the upper-to-lower direction. The rotor blades 8 and the stationary blades 9 form a turbine blade stage of the pump unit 20. Each stationary blade 9 is held with the stationary blade 9 being sandwiched between adjacent ones of spacers 10 in the upper-to-lower direction. The spacers 10 have the function of holding the stationary blades 9, as well as having the function of maintaining a gap between adjacent ones of the stationary blades 9 at a predetermined spacing.
A screw stator 11 forming a drag pump stage is provided at a subsequent stage (a lower side as viewed in the figure) of the stationary blades 9, and a gap is formed between an inner peripheral surface of the screw stator 11 and a cylindrical portion 12 of the rotor 2. The rotor 2 and the stationary blades 9 held by the spacers 10 are housed in a pump case 13 provided with a suction port 13a. When the shaft 3 attached to the rotor 2 is rotatably driven by a motor 6 with the shaft 3 being non-contact supported by the magnetic bearings 51A, 51B, 52, gas is exhausted from a suction port 13a side to a back pressure side, and the gas exhausted to the back pressure side is discharged by an auxiliary pump (not shown) connected to an exhaust port 26.
The power source unit 30 is bolted to a bottom surface side of the pump base 4 provided at the pump unit 20. The power source unit 30 configured to drivably control the pump unit 20 is provided with electronic components, the electronic components forming a main control section, a magnetic bearing drive control section, a motor drive control section, etc. These electronic components are housed in a housing of the power source unit 30.
The housing of the power source unit 30 includes a power source case 301 and a cooling jacket 302 covering an upper opening of the power source case 301. The cooling jacket 302 is provided with an opening 302a. A plug 324 of a cable 323 on a power source unit 30 side is connected to a receptacle 411 provided on a bottom surface of the pump base 4 through the opening 302a, and therefore, the power source unit 30 is connected to the pump unit 20.
The DC voltage for the motor 6 is input to an inverter 146. The DC voltage for the magnetic bearings is input to a DC power source 147 for the magnetic bearings. The magnetic bearings 51A, 51B, 52 illustrated in
A control section 144 is a digital arithmetic unit configured to control the motor and the magnetic bearings, and a field programmable gate array (FPGA) is used as the control section 144 in the present embodiment. The control section 144 outputs, to the inverter 146, a PWM control signal 401 for controlling ON/OFF of multiple switching elements included in the inverter 146, and outputs, to each excitation amplifier 143, a PWM control signal 403 for controlling ON/OFF of a switching element included in the excitation amplifier 143. Further, a sensor carrier signal (a carrier signal) 405 is input from the control section 144 to each sensor circuit 148. In addition, signals 402 relating to phase voltage and phase current for the motor 6 and electromagnet current signals 404 relating to the magnetic bearings are input to the control section 144. Moreover, a sensor signal 406 modulated by rotor displacement is input from each sensor circuit 148.
As illustrated in
The cooling jacket 302 is made of a metal material exhibiting excellent thermal conductivity, such as an aluminum material. The cooling jacket 302 includes a refrigerant passage 330 for circulating liquid refrigerant such as coolant water. In an example illustrated in
In
(C1) As described above, the power source integrated vacuum pump 1 is a vacuum pump configured such that the pump unit 20 as a pump main body and the power source unit 30 as a pump power source device are integrated together. The power source integrated vacuum pump 1 includes the substrate 311 which is provided at the power source unit 30 and on which the electronic components are mounted, the cooling jacket 302 as a cooling device having the cooling surface 303 fixed in contact with the substrate 311, and the heat insulating plates 350a, 350b as heat insulating members having a smaller coefficient of thermal conductivity than that of the material forming the cooling surface 303 and covering the region of the cooling surface 303 to which the substrate 311 is not fixed.
The heat insulating plates 350a, 350b are provided on an exposed surface (i.e., the region of the cooling surface 303 to which the substrate 311 is not fixed) of the cooling surface 303 of which temperature has been decreased by refrigerant, thereby covering the exposed surface. Thus, a contact area between the cooling surface 303 and air is reduced. In the example illustrated in
(C2) Further, the cooling device is configured as the cooling jacket 302 configured such that refrigerant circulates in the cooling jacket 302 and arranged between the pump unit 20 and the power source unit 30. This can prevent heat transfer from the pump unit 20 to the power source unit 30 or heat transfer from the power source unit 30 to the pump unit 20.
(C3) Further, the heat insulating plates 350a, 350b are screwed to the cooling surface 303 as illustrated in
For example, there is a case where some circuits are added or removed according to specifications of the power source unit 30. Of these circuits, an optional circuit for communication, an optional AC/DC circuit for three-system temperature adjustment, etc. are circuits with a great amount of heat generation, for example. Such optional circuits are fixed to the region where the heat insulating plates 350a, 350b of
Needless to say, the detachable heat insulating plates 350a, 350b as illustrated in
The embodiment and the variations have been described above, but the present invention is not limited to these contents. Other aspects conceivable within the scope of the technical idea of the present invention are also included in the scope of the present invention. For example, in the above-described embodiment, the power source integrated vacuum pump configured such that the pump unit 20 is the turbo-molecular pump has been described by way of example, but the pump unit 20 is not limited to the turbo-molecular pump.
Number | Date | Country | Kind |
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2017-086416 | Apr 2017 | JP | national |