Patent Description:
With the recent developments in electronics, there has been a drastically growing demand for semiconductor devices such as memories and integrated circuits. These semiconductor devices are manufactured by imparting electrical properties to an extremely pure semiconductor substrate (wafer) through doping of impurities to the substrate or by etching a semiconductor substrate to form a microscopic circuit thereon. These processes need to be executed inside a high-vacuum chamber in order to avoid any impact of dust in the air, etc. and generally a vacuum pump is used to exhaust the chamber, this vacuum pump already being well known (see <CIT> and<CIT>, for example).

This type of vacuum pump is provided with a pump main body and a control unit for controlling the drive of the pump main body by inputting/outputting power or a control signal to/from the pump main body. A wire cable formed by coating the outer circumference of a core wire with insulation vinyl or the like is used to input/output power or a control signal between the pump main body and the control unit. The number of wire cables used is approximately forty or more, taking up large space in the vacuum pump.

In a conventional vacuum pump such as those disclosed in <CIT> and <CIT>, wire cables that are each formed by coating the outer circumference of a core wire with insulation vinyl or the like are used to input/output power or a control signal between the pump main body and the control unit, as described above. For this reason, the wire cables take up large space in the vacuum pump, making the vacuum pump heavy and interfering with an attempt to reduce the size and weight of the vacuum pump.

Moreover, the wire cables are expensive, increasing the cost of the vacuum pump. Although each wire cable is flexible, bending a bundle of a plurality of wire cables at once requires great force, deteriorating the workability of the vacuum pump. The document wo <CIT>discloses a vacuum pump with a flexible printed circuit board. The document <CIT> teaches a method to attach and connect such a flexible printed circuit board to a multi-pin connector.

An object of the present invention is to solve the technical problems occurring when providing a vacuum pump with which size and weight reduction, improvement of workability, and cost reduction can be realized.

The present invention was contrived in order to achieve this object.

According to this configuration, a flexible printed wiring board is used on at least a part of the cable that is used for establishing electrical connection within the pump main body, electrical connection within the control unit, or electrical connection between the pump main body and the control unit, reducing the space taken up by the cable more as compared to a wire cable. Moreover, the flexible printed wiring board can be bent and pulled easily to a required position.

The invention set forth in claim <NUM> provides, according to the configuration described in claim <NUM>, a vacuum pump in which the control unit is attached to the pump main body.

According to this configuration, because the pump main body and the control unit are integrated, a compact vacuum pump can be realized.

According to the invention, electrical connection within the pump main body, electrical connection within the control unit, or electrical connection between the pump main body and the control unit can easily be established through the use of the flexible printed wiring boar and a connector, as specified by claim <NUM>.

According to the invention, a terminal of the flexible printed wiring board and the pins of the connector can be electrically connected to each other easily by inserting the pins of the connector into holes of the flexible printed wiring board.

The invention set forth in claim <NUM> provides, according to the configuration described in claim <NUM>, a vacuum pump in which the plurality of pins are arranged in symmetric positions with respect to a center of a direction in which the flexible printed wiring board extends, and the connector is provided with an indication means for indicating a direction of attaching the flexible printed wiring board.

According to this configuration, the flexible printed wiring board can be attached in the correct direction by attaching the flexible printed wiring board to the connector according to the instruction from the indication means of the connector.

The invention provides, according to claim <NUM>, a vacuum pump in which the flexible printed wiring board has a plurality of holes and a plurality of terminals surrounding the plurality of holes and connected to the wiring pattern.

According to this configuration, the terminals of the flexible printed wiring board and the pins of the connector can be electrically connected to each other easily by inserting the pins of the connector into the holes of the flexible printed wiring board.

The invention set forth in claim <NUM> provides, according to the configuration described in claim <NUM>, <NUM>, for <NUM>, a vacuum pump in which the flexible printed wiring board is provided with an indication means for indicating a direction of attaching the flexible printed wiring board.

According to this configuration, the flexible printed wiring board can be attached in the correct direction by attaching the flexible printed wiring board to the connector according to the instruction from the indication means of the flexible printed wiring board.

According to the invention set forth in claim <NUM>, the flexible printed wiring board is used on at least a part of the cable used for establishing electrical connection within the pump main body, electrical connection within the control unit, or electrical connection between the pump main body and the control unit, to reduce the space and weight of the cable, resulting in size/weight reduction of the vacuum pump. In addition, the materials used can be reduced and the cable can easily be pulled to a required position, improving the workability of the vacuum pump and achieving cost reduction.

According to the invention set forth in claim <NUM>, the pump main body and the control unit are integrated, realizing a compact vacuum pump. Consequently, in addition to the effect of the invention of claim <NUM>, the effect of size reduction can be expected.

According to the invention set forth in claim <NUM>, electrical connection within the pump main body, electrical connection within the control unit, or electrical connection between the pump main body and the control unit can easily be established through the use of the flexible printed wiring board and the connector.

According to the invention set forth in claim <NUM>, the flexible printed wiring board and the connector can be electrically connected to each other easily by inserting the pins of the connector into the holes of the flexible printed wiring board. Consequently, in addition to the effect of the invention of claim <NUM>, further improvement of the workability of the vacuum pump and cost reduction can be expected.

According to the invention set forth in claim <NUM>, the flexible printed wiring board can be attached in the correct direction by attaching the flexible printed wiring board to the connector according to the instruction from the indication means of the connector. Consequently, in addition to the effect of the invention of claim <NUM>, further improvement of the workability of the vacuum pump and reliability thereof can be expected.

According to the invention set forth in claim <NUM>, the terminals of the flexible printed wiring board and the pins of the connector can be electrically connected to each other easily by inserting the pins of the connector into the holes of the flexible printed wiring board. Consequently, further improvement of the workability of the vacuum pump and reliability thereof can be expected.

According to the invention set forth in claim <NUM>, the flexible printed wiring board can be attached in the correct direction by attaching the flexible printed wiring board to the connector according to the instruction from the indication means of the flexible printed wiring board. Consequently, in addition to the effect of the invention of claim <NUM>, <NUM>, or <NUM>, further improvement of the workability of the vacuum pump and reliability thereof can be expected.

In order to achieve the object of the present invention, which is to provide a vacuum pump with which size and weight reduction, improvement of workability, and cost reduction can be realized, the present invention has designed a vacuum pump in which a pump main body with a rotor and a control unit for controlling the drive of the pump main body are electrically connected to each other by a cable through which power or a control signal is input/output, wherein the cable is formed with a flexible printed wiring board configured by printing a wiring pattern on a surface of a sheet-like insulating substrate.

An example of a vacuum pump according to an embodiment of the present invention is described hereinafter in detail with reference to the drawings.

<FIG> and <FIG> each show a vacuum pump according to the present invention. <FIG> is a cross-sectional diagram of the vacuum pump in which a control unit is attached to a pump main body. <FIG> is a cross-sectional diagram of the vacuum pump in which the control unit is detached from the pump main body.

In <FIG> and <FIG>, a vacuum pump <NUM> has a pump main body <NUM> for vacuum exhaustion and a control unit <NUM> for controlling the drive of the pump main body <NUM>. The control unit <NUM> is attached removably to a lower surface of the pump main body <NUM>. The control unit <NUM> and the pump main body <NUM> are electrically connected to each other by cables <NUM>, <NUM>, described hereinafter, and power or a control signal can be input/output through the cables <NUM>, <NUM>.

More specifically, the pump main body <NUM> has an inlet port <NUM> formed at an upper end of a tubular outer cylinder <NUM>. Inside the outer cylinder <NUM>, there is provided a rotor <NUM> on which a plurality of rotary blades <NUM> for suctioning and pumping out the gas are formed, the rotary blades being formed in multiple steps on circumferential portions of the rotor <NUM>.

A rotor shaft <NUM> is attached to the middle of the rotor <NUM>. The rotor shaft <NUM> is, for example, supported in a floating manner in midair and has its position controlled by a <NUM>-axis control magnetic bearing.

Upper radial electromagnets <NUM> are constituted by four, i.e. two pairs of, electromagnets, the two pairs of electromagnets being disposed in the X-axis and the Y-axis, respectively. Four upper radial sensors <NUM> are provided in the proximity of the upper radial electromagnets <NUM> so as to correspond thereto. The upper radial sensors <NUM> detect a radial displacement of the rotor <NUM> and transmit a signal indicating the radial displacement to a control circuit <NUM> of the control unit <NUM> through the cables <NUM>, <NUM>.

Based on the displacement signal transmitted by the upper radial sensors <NUM>, the control unit <NUM> controls the excitation of the upper radial electromagnets <NUM> by means of an output of the control circuit <NUM> having a PID adjustment function, and adjusts the upper radial position of the rotor shaft <NUM>. The control circuit <NUM> converts an analog sensor signal corresponding to a displacement of the rotor shaft <NUM> detected by the upper radial sensors <NUM> into a digital signal using an A/D converter, processes the digital signal, and raises the rotor shaft <NUM> by adjusting the current that flows through the upper radial electromagnets <NUM>.

In order to make fine adjustments to the current that flows through the upper radial electromagnets <NUM>, the current flowing through the upper radial electromagnets <NUM> is measured and fed-back to the control circuit <NUM>.

The rotor shaft <NUM> is made out of a material of high permeability (e.g., iron) and is drawn by the magnetic force of the upper radial electromagnets <NUM>. This adjustment is performed in the X-axis direction and the Y-axis direction separately.

Lower radial electromagnets <NUM> and lower radial sensors <NUM> are disposed in the same manner as the upper radial electromagnets <NUM> and the upper radial sensor <NUM>, and the lower radial position of the rotor shaft <NUM> is adjusted by the control unit <NUM>, as with the upper radial position of the same.

Axial electromagnets 26A, 26B are disposed above and below a circular metal disc <NUM> provided in the lower portion of the rotor shaft <NUM>, in such a manner as to sandwich the metal disc <NUM>. The metal disc <NUM> is made out of a material of high permeability such as iron. An axial sensor <NUM> is provided facing an axial end surface of the rotor shaft <NUM> in order to detect an axial displacement of the rotor shaft <NUM>, wherein an axial displacement signal is transmitted to the control circuit <NUM>.

Based on this axial displacement signal, the excitation of the axial electromagnets 26A, 26B is controlled by means of an output of an amplifier that is obtained through the control circuit <NUM> of the control unit <NUM> that has a PID adjustment function. The axial electromagnet 26A draws the metal disc <NUM> upward using the magnetic force thereof, while the axial electromagnet 26B draws the metal disc <NUM> downward.

The control unit <NUM> properly adjusts the magnetic force of the axial electromagnets 26A, 26B acting on the metal disc <NUM> in this manner, to keep the rotor shaft <NUM> floating magnetically in the axial direction in the pump main body <NUM> so that the rotor shaft <NUM> stays non-contact in the space.

A motor <NUM> has a plurality of magnetic poles that are disposed circumferentially to surround the rotor shaft <NUM>. Each of these magnetic poles is controlled to rotary drive the motor <NUM> based on a power signal that is output from a drive circuit through a motor control circuit of the control unit <NUM> that has a PWM control function. In addition, a rotation speed sensor and a motor temperature sensor, both not shown, are attached to the motor <NUM>, and the control circuit <NUM> of the control unit <NUM> controls the rotation of the rotor shaft <NUM> in response to detection signals from the rotation speed sensor and the motor temperature sensor.

A plurality of stator blades <NUM> are arranged with small distances to the rotary blades <NUM>. The rotary blades <NUM> transfer the exhaust gas molecules downward by collision and are therefore inclined by a predetermined angle from a plane perpendicular to the axis of the rotor shaft <NUM>.

The stator blades <NUM>, too, are inclined by a predetermined angle from the plane perpendicular to the axis of the rotor shaft <NUM>, and are also arranged alternately with the rotary blades <NUM>, facing the inside of the outer cylinder <NUM>. One end of each stator blade <NUM> is inserted and supported between a plurality of stacked stator blade spacers <NUM>.

Each of the stator blade spacers <NUM> is a ringshaped member and made out of metal such as aluminum, iron, stainless steel, or copper, or a metal alloy containing these metals. The outer cylinder <NUM> is fixed to the outer circumferences of the stator blade spacers <NUM> with a small space therebetween. The bottom portion of the outer cylinder <NUM> is provided with a base portion <NUM>, and a threaded spacer <NUM> is disposed between the lower portion of the stator blade spacers <NUM> and the base portion <NUM>. An outlet port <NUM> is formed below the threaded spacer <NUM> inside the base portion <NUM> and is communicated to the outside.

The threaded spacer <NUM> is a cylindrical member made out of aluminum, copper, stainless steel, iron or a metal alloy containing these metals. Although not shown, a plurality of spiral thread grooves are engraved on the inner circumferential surface of the threaded spacer <NUM>. The direction of the spiral of each thread groove is the direction in which the molecules of the exhaust gas are transferred toward the outlet port <NUM> when moving in the rotational direction of the rotor <NUM>.

A rotary blade <NUM> is suspended at the lowest portion leading to the rotary blades <NUM> of the rotor <NUM>. The outer circumferential surface of the rotary blade <NUM> is shaped into a cylinder, protrudes toward the inner circumferential surface of the threaded spacer <NUM>, and is positioned adjacent to the inner circumferential surface of the threaded spacer <NUM> with a predetermined distance therebetween.

The base portion <NUM> is a disk-shaped member configuring the bottom portion of the pump main body <NUM> and is generally made out of metal such as iron, aluminum, or stainless steel.

Because the base portion <NUM> functions not only to physically retain the pump main body <NUM> but also as a thermal conduction path, it is preferred that rigid metal of high thermal conductivity such as iron, aluminum, or copper be used.

At the lower surface of the base portion <NUM>, the cable <NUM> provided on the pump main body <NUM> side and the cable <NUM> provided on the control unit <NUM> side are connected, and then the control unit <NUM> is removably attached by a bolt or the like coaxially with the shaft center of the pump, assembling a compact, small vacuum pump. When attaching the control unit <NUM>, a sealing member <NUM> is disposed between the base portion <NUM> and the control unit <NUM> so that the inside of the pump main body <NUM> can be kept evacuated.

The cable <NUM> provided on the pump main body <NUM> side and the cable <NUM> provided on the control unit <NUM> side are each configured with a flexible printed wiring board <NUM> and a connector <NUM> attached to one end of the wiring board <NUM>. Furthermore, the cable <NUM> and the cable <NUM> basically share the same structure, except that the other end of the flexible printed wiring board <NUM> on the pump main body <NUM> side is attached to a terminal block of the pump main body <NUM>, not shown, while the other end of the flexible printed wiring board <NUM> on the control unit <NUM> side is connected to a circuit board of the control circuit <NUM>, and that the connector <NUM> on the pump main body <NUM> side and the connector <NUM> on the control unit <NUM> side are a male terminal and a female terminal respectively and are detachable from each other. The structure of the cables <NUM>, <NUM> is described hereinafter with reference to <FIG>, mainly with the cable <NUM> provided on the pump main body <NUM> side.

As shown in <FIG>, the cable <NUM> is configured with the flexible printed wiring board <NUM> and the connector <NUM> attached to one end of the flexible printed wiring board <NUM>.

As shown in detail in <FIG> in addition to <FIG>, the connector <NUM> is configured with a cylindrical connector main body <NUM>, the outer circumference of which is provided integrally with a fitting flange <NUM>, a plurality of contact pins (terminals) <NUM> arranged in parallel configuration in the axial direction in the connector main body <NUM>, an insulator <NUM> for electrically insulating the contact pins <NUM> from each other, and the like. The plurality of contact pins <NUM> are arranged in an orderly fashion so as to be symmetric with respect to a center line O extending in the direction in which the flexible printed wiring board <NUM> extends. Each of the contact pins <NUM> has one end side thereof connected to the flexible printed wiring board <NUM> and protruding significantly from the connector main body <NUM> to the outside, as shown in <FIG> and <FIG>. The other end sides of the contact pins <NUM> are connected to the connector <NUM> provided on the control unit <NUM> side and protrude into the space of the connector main body <NUM> so as to be connected to a plurality of respective female contact pins provided to the connector <NUM> of the control unit <NUM>.

The flexible printed wiring board <NUM> is obtained by printing a plurality of electric circuits <NUM>, i.e., a wiring pattern, on a sheet-like insulating substrate (e.g., a plastic film) having a thickness t (see <FIG>) of <NUM> to <NUM> using copper foil or the like of approximately <NUM> to <NUM> in thickness. One end side of each of the electric circuits <NUM> has a through-hole <NUM> that corresponds to each of the contact pins <NUM> of the connector <NUM> and is configured with a through-hole through which each of the contact pins <NUM> can be inserted and a terminal surrounding the through-hole. Therefore, the through-holes <NUM> on the flexible printed wiring board <NUM> are arranged in an orderly fashion so as to be symmetric with respect to the center line O extending in the direction in which the flexible printed wiring board <NUM> extends. Moreover, the number of electric circuits <NUM> is not the same as the number of contact pins <NUM> of the connector <NUM>; thus, the electric circuits <NUM> are each provided in a portion that needs to be connected to the control circuit <NUM> of the control unit <NUM>. The sheet section of a portion that does not need to be connected to the control unit <NUM> is cut to not interrupt the connection (e.g., the part shown by reference numeral <NUM>). Note that, in the present example, twenty-one contact pins <NUM> are connected to the through-holes <NUM> corresponding to these contact pins <NUM>, as shown in <FIG>.

In the cable <NUM> configured in the manner described above, the through-holes <NUM> of the flexible printed wiring board <NUM> are made correspondent to the contact pins <NUM> of the connector <NUM>, and the contact pins <NUM> are inserted into the through-holes <NUM> to establish engagement therebetween, as shown in <FIG>. Thereafter, the connector <NUM> and the flexible printed wiring board <NUM> are electrically fixed and connected to each other by soldering the contact pins <NUM> and the through-holes <NUM> together by solder dipping or the like.

Since the flexible printed wiring board <NUM> of the resultant cable <NUM> is bent freely, the connectors <NUM>, <NUM> can be mechanically and electrically connected to each other between the pump main body <NUM> and the control unit <NUM> by pulling the flexible printed wiring board <NUM> freely to a required position. In case of a conventional wire cable, the cable cannot be bent freely and forms a large bundle of wires, requiring a hatched area <NUM> shown in <FIG>. On the other hand, when the flexible printed wiring board <NUM> of the present example is used, the area <NUM> is eliminated and the space and weight of the cable <NUM> can be reduced, accomplishing size/weight reduction of the vacuum pump.

In the cable <NUM> shown in <FIG>, the upper electric circuits <NUM> above the center line O extending in the direction in which the flexible printed wiring board <NUM> extends receive signals from the upper radial sensor <NUM> and the like, while the lower electric circuits <NUM> below the center line O receive signals from the lower radial sensors <NUM> and the like. Thus, in the case where the electric circuits <NUM> and the through-holes <NUM> are symmetric with respect to the center line O of the flexible printed wiring board <NUM>, the flexible printed wiring board <NUM> is connected to the connector <NUM> when the upper and lower electric circuits and through-holes are reversed with respect to the center line O, i.e., when the flexible printed wiring board <NUM> is flipped over and attached to the connector <NUM>.

When attaching the flexible printed wiring board <NUM> is flipped over and attached and connected to the connector <NUM>, a problem might occur, depending on the terminal block of the pump main body, because the signals that are input from the upper radial sensors <NUM> and the lower radial sensors <NUM> to the control circuit <NUM> are reversed. In the present embodiment, as shown in <FIG> and <FIG>, one surface of the flexible printed wiring board <NUM> and one surface of the connector <NUM> are provided with triangle, colored marks 51a, 51b, respectively, which function as indication means for indicating the direction of attaching the flexible printed wiring board <NUM> to the connector <NUM>. Therefore, when assembling these parts, incorrect installation can be prevented by abutting the mark 51a of the flexible printed wiring board <NUM> against the mark 51b printed on the connector <NUM>, with the surface of the flexible printed wiring board <NUM> with the mark 51a facing up.

The indication means is not limited to the triangle, colored marks 51a, 51b. For instance, a geometrical mark or a color may be formed between the flexible printed wiring board <NUM> and the connector <NUM>, to indicate the direction of attaching the flexible printed wiring board <NUM> to the connector <NUM>. The mark as the indication means may be provided only to the flexible printed wiring board <NUM> (mark 51a), only to the connector <NUM> (mark 51b), or to both the flexible printed wiring board <NUM> (mark 51a) and the connector <NUM> (mark 51b).

The operations of the vacuum pump <NUM> configured in the manner described above are described next. First, once the rotary blades <NUM> are driven by the motor <NUM> and rotated along with the rotor shaft <NUM>, the exhaust gas of the chamber is suctioned through the inlet port <NUM> due to the actions of the rotary blades <NUM> and the stator blades <NUM>. The exhaust gas suctioned through the inlet port <NUM> is transferred to the base portion <NUM> through the spaces between the rotary blades <NUM> and the stator blades <NUM>. The exhaust gas that is transferred to the base portion <NUM> is sent to the outlet port <NUM> while being guided by the thread grooves of the threaded spacer <NUM>. The inside of the chamber can be evacuated by continuing this operation.

The present embodiment has indicated that the threaded spacer <NUM> is disposed on the outer circumference of the rotary blades <NUM> and that the thread grooves are engraved on the inner circumferential surface of the threaded spacer <NUM>. However, in contrast to this, sometimes the thread grooves are engraved on the outer circumferential surface of the rotary blades <NUM>, and a spacer with a cylindrical inner circumferential surface is disposed around the thread grooves.

The inside of the vacuum pump is kept at a predetermined pressure by purge gas so that the gas suctioned through the inlet port <NUM> does not enter the electric component configured with the motor <NUM>, the lower radial electromagnets <NUM>, the lower radial sensors <NUM>, the upper radial electromagnets <NUM>, the upper radial sensors <NUM>, and the like.

For this reason, a pipe that is not shown is disposed in the base portion <NUM>, wherein the purge gas is introduced through this pipe. The introduced purge gas is fed to the outlet port <NUM> through the space between a protective bearing <NUM> and the rotor shaft <NUM>, the space between the rotor and stator of the motor <NUM>, and the space between a stator column <NUM> and each rotary blade <NUM>.

The present embodiment has disclosed a structure in which the control unit <NUM> is attached to the lower surface of the pump main body <NUM> (the lower surface of the base portion <NUM>) and integrated with the pump main body <NUM>. However, the control unit <NUM> may be provided in a location separate from the pump main body <NUM>.

In this case, the cable <NUM> pulled out from the pump main body <NUM> may be fixed to a cable extending from a control unit, not shown, through the connector <NUM> by freely pulling the flexible printed wiring board <NUM> in the pump main body <NUM> and fixing the connector <NUM> attached to a tip end of the flexible printed wiring board <NUM> to a side surface of the pump main body <NUM>. This attachment performed here is done so that the inside of the pump main body <NUM> is kept evacuated by having the sealing member <NUM>, not shown, between the base portion <NUM> and the connector <NUM>. The configuration of the vacuum pump <NUM> shown in <FIG> and the configuration of the vacuum pump <NUM> shown in <FIG> and <FIG> are different from each other in that the control unit is provided in another location, but share the same basic configuration of the pump main body <NUM>. Therefore, the same reference numerals are used on the same members, and the overlapping descriptions thereof are omitted accordingly.

Note that the present invention has indicated that the flexible printed wiring board configures part of the electrical connection such as a signal line of a radial or axial sensor of a magnetic bearing with less current or a signal line of a rotation speed sensor. However, the configuration of the flexible printed wiring board is not limited thereto, and all the signal lines may be connected by the flexible printed wiring board <NUM>.

In addition, the flexible printed wiring board <NUM> may be a plurality of layers of flexible printed wiring boards. Such a configuration can reduce the width of the flexile printed wiring boards, resulting in a compact vacuum pump.

The number of flexible printed wiring boards does not have to be one. A configuration can be employed in which a plurality of flexible printed wiring boards are stacked on top of each other, as exemplified in <FIG> where a flexible printed wiring board <NUM>(A) and a flexible printed wiring board <NUM>(B) are stacked and wired together. In this case, for example, the flexible printed wiring board <NUM>(B) may be configured as a flexible printed wiring board for electrical connection having a motor electric power line for the motor or large current such as excitation current for the magnetic bearing, and the flexible printed wiring board <NUM>(A) may be configured as a printed wiring board for electrical connection having small current. Configuring the flexible printed wiring boards in this manner allows the thickness of the insulation layer of each wiring board to be changed easily. In so doing, interference with the pins of a vacuum connector can be prevented by changing the length of the pins.

Claim 1:
A vacuum pump (<NUM>), comprising:
a pump main body (<NUM>) with a rotor (<NUM>); and
a control unit (<NUM>) for controlling a drive of the pump main body (<NUM>),
an electrical connection in the pump main body (<NUM>), an electrical connection in the control unit (<NUM>), or an electrical connection between the pump main body (<NUM>) and the control unit (<NUM>), in the vacuum pump (<NUM>), being realized by a cable (<NUM>, <NUM>), wherein
at least a part of the cable (<NUM>,<NUM>) is configured with a first flexible printed wiring board (<NUM>) obtained by forming a wiring pattern (<NUM>) on a surface of a sheet-like insulating substrate,
the first flexible printed wiring board (<NUM>) has a connector (<NUM>) attached to at least one end side thereof,
the connector (<NUM>) comprises a plurality of pins, a first plurality of the pins being connected to the wiring pattern of the first flexible printed wiring board (<NUM>), characterized in that the first plurality of the pins is less than all of the plurality of pins, such that pins that are not connected to the wiring pattern of the first flexible printed wiring board (<NUM>) form a second plurality of pins located on the same side of the connector (<NUM>) as the first plurality of the pins and outside of an end edge of the first flexible printed wiring board (<NUM>), and
the first flexible printed wiring board (<NUM>) defines a plurality of holes (<NUM>) and a plurality of terminals surrounding the plurality of holes (<NUM>) and connected to the wiring pattern, the first plurality of the pins being received into the plurality of holes (<NUM>) for connection to the wiring pattern of the first flexible printed wiring board (<NUM>),