JPH0649120Y2 - Fan sensor - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application This invention relates to a fan sensor for detecting abnormal rotation of a cooling fan motor used in a vacuum pump such as a turbo molecular pump or other electronic equipment.

(B) Prior Art As shown in FIG. 4, a fan sensor of this type is conventionally arranged close to the cooling fan in order to detect the rotation of the cooling fan driven by a fan motor (not shown). The detection unit 1 including a magnetic sensor, the comparison unit 2 that compares the period of the pulse signal from the detection unit 1 with a reference period that is predetermined corresponding to the reference rotation speed of the fan motor, and the comparison unit 2 It is composed of an integrator circuit 3 for integrating the comparison output, a relay controlled by the output of the integrator circuit 3, and the like.

The fan sensor described above compares the cycle of the pulse signal from the detection unit 1 with a predetermined reference cycle, so that when the rotation speed of the fan motor becomes lower than the reference rotation speed,
By opening / closing the relay contact of the relay 4, the abnormality of the rotation of the motor is notified. However, since the rotation speed of the fan motor is lower than the reference rotation speed when the motor is started, this fan sensor has a drawback that it outputs an abnormal signal when the motor is started.

In order to solve this drawback, a fan sensor provided with a timer for stopping the comparison operation of the comparison unit 2 has been devised and implemented for a fixed time required for the fan motor to reach the reference rotation speed. This type of fan sensor is a so-called normally closed (N) circuit that closes the relay contact when the fan motor normally rotates in relation to the type of relay provided on the output side.
There are a C) type fan sensor and a so-called normally open (NO) type fan sensor in which the relay contacts are opened during normal rotation.

Hereinafter, a case where such a fan sensor is used in a state as shown in FIG. 5 will be described, and its problems will be pointed out.

In FIG. 5, 5 is a turbo molecular pump, and 6 is a fan part for cooling the turbo molecular pump 5. In addition to the cooling fan and the fan motor that drives the cooling fan, the fan unit 6 is provided with the above-described fan sensor that detects the rotation of the cooling fan. Reference numeral 7 is a power supply for supplying electric power to the turbo molecular pump 5 via the code 8a. The power supply 7 further supplies power to the fan motor and the fan sensor of the fan unit 6 via the cord 8b. 8c
Is a fan sensor cord connected to the relay contact of the fan sensor, and this cord 8c is connected to, for example, the alarm device 9. The alarm device 9 notifies abnormal rotation of the fan motor according to the open / close state of the relay contact.

When the rotation of the fan motor of the turbo molecular pump 5 as described above is detected by the normally closed type fan sensor, when the fan motor is rotating normally, the relay coil is not energized due to the configuration of the fan sensor. The contacts are closed. On the contrary, when the rotation speed of the fan motor decreases due to a failure of the fan motor, the relay contact is opened. On the other hand, if the fan sensor cord 8c is disconnected at the connector portion of the fan unit 6, for example, the alarm device 9 determines that the relay contact of the fan sensor is open regardless of whether the relay contact is open or closed. Also fan code 8b
When power is not supplied to the fan motor and the fan sensor of the fan unit 6 due to the disconnection, the relay contact is closed. Similarly, in the event of a power failure, the relay contacts will be closed.

On the other hand, when the normally open type fan sensor is used, the relay contact is opened during normal rotation, and the relay contact is closed when the rotation speed is reduced. If the fan sensor cord 8c is disconnected, the alarm device 9 determines that the relay contact is in the open state as described above. When the fan cord 8b comes off or a power failure occurs, the relay contacts are open.

The above results are summarized in Table 1.

By the way, fan sensor cord 8c and fan cord 8b
There is a demand for detection of fan rotation failure, fan failure, and power failure as fan motor rotation abnormality. But first
As can be seen from the table, when a normally closed fan sensor is used, the relay contact is closed even when the fan cord 8b comes off during normal rotation and when there is a power failure, making it impossible to distinguish between normal and abnormal The problem arises.

When using a normally open fan sensor,
In addition to the open state at the time of normal rotation, the relay contact is also opened at the time of disconnection of the fan sensor cord 8c and the fan cord 8b, and at the time of a power failure, which causes the same problem as described above. As described above, when the conventional normally closed or normally open fan sensor is used, the above-described requirements cannot be satisfied.

(C) Purpose This invention is intended to prevent the fan sensor cord and the fan cord from being disconnected, without outputting an abnormal signal when the motor is started.
It is an object of the present invention to provide a fan sensor that outputs an abnormal signal in the event of fan failure or power failure.

(D) Configuration In the fan sensor according to the present invention, the detection unit that detects the rotation of the blades of the fan motor, and the cycle of the pulse signal from the detection unit are set in advance corresponding to the reference rotation speed of the fan motor. A comparison unit that compares with a reference period, a timer that stops the comparison operation of the comparison unit for a certain period of time after the motor is started, an integration circuit that integrates the comparison output given from the comparison unit, and an output of the integration circuit. A normally open-type first relay controlled by the fan sensor main body, and a normally open type connected to the relay contact of the first relay in series and driven by the power source of the fan sensor main body. It is characterized by having a second relay of the mold.

(E) Embodiment FIG. 1 is a block diagram schematically showing the configuration of a fan sensor according to an embodiment of the present invention. In the figure, the same parts as those in FIG. 4 are designated by the same reference numerals.

Reference numeral 5 is a timer that stops the comparison operation of the comparison unit 2 for a certain period of time after the motor is started. The detection unit 1, the comparison unit 2, the integration circuit 3, the first relay 4 and the timer 5 constitute a fan sensor main body.

Reference numeral 6 is a normally open type relay, the relay coil of which is connected in series with the relay contact of the first relay 4 and is driven by the power source of the fan sensor main body.

FIG. 2 is a circuit diagram showing a specific configuration of the fan sensor shown in FIG.

In FIG. 2, portions corresponding to those in FIG. 1 are shown surrounded by broken lines.

The comparison unit 2 performs digital-analog comparison, and the variable resistor R1 and the charging capacitor are set so that the charging time constant can be set arbitrarily.
An RC series circuit composed of C1 and a unijunction transistor UJT whose emitter is connected to the connection point of R1 and C1 and a collector connected to the emitter of this UJT, which corresponds to the rotation speed of the fan motor from the detection unit 1 It is composed of a first transistor Tr.1, etc., which becomes conductive by the arrival of the input pulse signal of the above-mentioned period and constitutes the discharge path of the charging capacitor C1.

The integrating circuit 3 includes the unijunction transistor UJ.
A second transistor Tr.2, whose base is connected to the base of T via a diode D1 in the forward direction, is provided with a capacitor C2 connected between the crevice bases of the transistor Tr.2, which is the output terminal thereof. The relay coil Ry of the first relay 4 is connected to the collector of the transistor Tr / 2. The relay coil Ry of the second relay 6 is the relay 4
It is connected in series to the relay contact of. And relay 6
Both contacts are led to the outside and connected to, for example, an alarm device (not shown).

Timer 5 is a diode D4 with its output end connected in the opposite direction.
Comparator A connected to the emitter of UJT via a resistor R
4 and the capacitor C3 are connected in series, and the connection point is connected to the positive terminal of the comparator A, the RC series circuit, and the resistors R5 and R
6 and 6 are connected in series, and the connection point is composed of a voltage dividing circuit or the like connected to the negative terminal of the comparator A.

In this circuit, the positive terminal + Vcc of the power supply is the relay coil Ry of the relay 4 and one relay contact, the base of the unijunction transistor UJT via the resistor R2, and the emitter of the UJT via the variable resistor R1 and the diode D3.
The power supply terminal of the comparator A and the resistors R4 and R5 are respectively connected to one ends. The negative terminal Com is the charging capacitor C
1, via the resistor R3, the base of the UJT, each emitter of the first and second transistors Tr.1, Tr.2, the relay coil Ry of the relay 6, the ground terminal of the comparator A, one of the resistor R6 and the capacitor C3 Connected to each end.

Next, the operation of the fan sensor shown in FIG. 2 will be described with reference to FIG.

As you know, unijunction transistor UJT
The current hardly flows between the two bases until a voltage at which the voltage-current characteristic between the emitter and the base is bent to the negative resistance region, that is, the mountain voltage Vp is applied to the emitter. Therefore, in the circuit shown in Fig. 2, the emitter of UJT has a time constant R1 determined by the values of resistor R1 and charging capacitor C1.
・ Voltage that rises according to C1, that is, UJT is kept in the cut-off state until this voltage reaches Vp, and it becomes conductive only when Vp is exceeded, and current is passed through resistor R3, and the pulse voltage is applied to point b in the figure. Generate.

However, in the circuit shown in Fig. 2, the emitter of the unijunction transistor UJT is connected to the collector of the first transistor Tr.
Since it is configured to be performed depending on the presence or absence of the input pulse signal from the detection unit 1 applied to the base of 1,
When the first transistor becomes conductive due to the arrival of the input pulse signal before the emitter potential of the UJT rises to the above-mentioned Vp point, the charge accumulated in the charging capacitor C1 becomes
The closed circuit of C1-> Tr-1 collector-> same emitter-> C1 is used as the discharge path for discharging, so the potential of the UJT emitter drops sharply before reaching Vp, and UJT remains in a conducting state. Becomes

Therefore, as long as an input pulse signal of a period shorter than the rising period of the emitter potential of UJT, which is determined by the time constant set by R1 and C1 described above, is applied to the input terminal (Input), the output terminal of the comparison circuit 3 That is, no output is generated between be in FIG.

Therefore, since the transistor Tr.2 is turned off, the relay coil Ry of the relay 4 is not excited, and the relay contact is closed. As a result, the relay coil Ry of the relay 6 is energized, and the relay contact of the relay 6 is closed. Thus, for example, when the rotation speed of the fan motor is the normal rotation speed equal to or higher than the reference rotation speed, the contact of the relay 6 is closed to indicate that the rotation is normal.

The situation of this operation is as shown in FIG. 3 (a), and it can be seen that the potential between ae, that is, the emitter potential of UJT, does not fall below Vp and is repeated due to the period Tc of the input pulse signal. .

On the other hand, when the input pulse signal arrives at a cycle longer than the cycle Tc, as shown in FIG.
The emitter potential of T (voltage between ae) rises to Vp once,
As a result, the UJT becomes conductive, and as a result, a pulse output is generated at point b in FIG. 2 like the voltage between be shown in FIG. This means that the cycle of the input pulse signal is longer than the rising cycle of the UJT emitter potential determined by the time constant set by R1, that is, the actual rotation speed of the fan motor is lower than the reference rotation speed. To do.

When integrating this pulse output by the integrating circuit 3,
After the input to the integrating circuit 3, the diode D1 is inserted in the circuit of the present invention for the purpose of holding it.

The means for holding the pulse signal by the diode D1 is not a problem if the integrator circuit has a high gain in general, but in the present invention, the integrator circuit 3 has a purpose of simplifying the circuit configuration as much as possible. The active element is the second transistor
Only Tr / 2 is available. Therefore, the presence of the diode D1 as the input impedance element acts as a low resistance in the forward direction when the integration circuit is charged by the pulse output and acts as a high resistance in the reverse direction when discharging, which is one factor in selecting the integration time constant. Brings two characteristics.

Therefore, the pulse output of the comparator 2 is the transistor Tr.
Is transmitted as an integrated output signal to the collector of the above, which is shown as the voltage between ce in FIG. 3 (b).
As a result, the relay coil Ry of the relay 4 connected to the collector of the transistor Tr.2 is excited, and the relay contact of the relay 4 is opened. As a result, the relay coil Ry of the relay 6 is de-energized, and the relay contact of the relay 6 is opened. In this way, for example, when the rotation speed of the motor decreases due to a fan failure, the relay contact of the relay 6 is opened to notify the abnormality.

Next, the operation at the time of other abnormality will be described.

For example, when the fan sensor cord 8c is disconnected as shown in FIG. 5, the alarm device 9 determines that the contact of the relay 6 is open regardless of whether the contact of the relay 6 is open or closed.

When the fan cord 8b is disconnected and the power supplied to the fan motor and the fan sensor is cut off, the relay coil Ry of the relay 6 is de-energized and the contact of the relay 6 is opened.

Similarly, the contacts of the relay 6 are open even during a power failure.

As described above, in the fan sensor shown in FIGS. 1 and 2, the contact of the relay 6 is closed only when the fan motor is normally rotating, and the rotation speed of the fan sensor is reduced due to a failure of the fan. When the fan sensor cord 8c and the fan cord 8b are disconnected or a power failure occurs, the contact of the relay 6 is opened.

Next, the operation of the fan sensor when the fan motor is started, that is, when the power is turned on will be described.

When the power source Vcc is turned on, the reference voltage Vcc · R6 / determined by the resistors R5 and R6 is applied to the negative terminal of the comparator A of the timer 5.
(R5 + R6) is given. On the other hand, charging of the capacitor C3 is started via the resistor R4. Time constant R of this RC series circuit
4 · C3 is determined corresponding to the time T ₀ required from the power is turned on to the normal rotation of the motor, and is input to the negative terminal of the comparator A from the power on to the time T _0. The reference voltage is set to be higher than the charging voltage of the capacitor C3. Therefore, from power-on to time T ₀ ,
The comparator A is in the L state. The emitter of the UJT of the comparison unit 2 is a diode D4 which is in the forward direction with respect to the output of the comparator A.
Since it is connected to the output of the comparator A via, the operation of UJT is stopped during the time T ₀ . As a result, during the time T ₀ , the relay contact of the first relay 4 is closed and the second relay 4 is closed.
Since the relay coil Ry of the relay 6 is energized, it indicates that the relay contact of the relay 6 is closed, that is, normal.

In this way, the comparison operation is stopped for a certain period of time after the motor is started, and in order to distinguish between normal rotation and other abnormal rotations, the normally closed fan sensor body described above and the normally open type fan sensor body connected to the fan sensor body are connected. It is realized by combining with a relay. By the way, Table 2 shows that when using a device obtained by combining other fan sensors and relays, it is impossible to distinguish between normal rotation as described above and other abnormal rotation.

In Table 2, combination I is a fan sensor realized by a combination of the normally closed fan sensor body according to the present invention and the normally open second relay 6, and combination II is a normally closed fan sensor. Combination using the main body and normally closed relay 6
III shows a combination of a normally open type fan sensor main body and a normally open type relay 6, and combination IV shows a combination of a normal open type fan sensor main body and a normally closed type relay. It should be noted that “fan sensor cord disconnection” in the same table means that the second relay 6
Regardless of the actual open / closed state of the relay contact, the alarm device 9 to which one end of the fan sensor cord 8c is connected determines that the relay contact is in the open state, and therefore any combination is “open”. . As is clear from Table 2, in the combinations II to IV, the same contact state as the contact state of the second relay 6 at the time of normal rotation appears even at other abnormal times. Therefore, it can be seen that it is not possible to judge whether the motor is rotating normally or abnormally depending on the combination thereof, and it is judged only by the combination I.

(F) Effect The fan sensor according to the present invention includes a so-called normally-closed fan sensor main body, which stops the comparison unit in the sensor main body for a certain period of time after the motor is started and is connected in series with the relay contact of the sensor main body. A normally open relay is connected and this relay is driven by the power supply of the fan sensor body.

Therefore, according to this invention, it is possible to prevent the output of the abnormal signal due to the detection of the low rotation speed at the time of starting the motor, and at the same time, the failure of the fan motor at the normal time, the fan sensor cord, the disconnection of the fan cord, the power failure, etc. It is possible to output the status as abnormal and display that fact only when the fan motor is rotating normally. In this way, this device outputs an abnormal signal only during normal rotation, so it is ideal as a rotation detector for fan motors, and various devices that use cooling fans may fail in fan motors, forget to attach cords, etc. It is possible to prevent damage due to overheating.

[Brief description of drawings]

FIG. 1 is a block diagram schematically showing the structure of a fan sensor according to an embodiment of the present invention, FIG. 2 is a concrete circuit configuration diagram of the fan sensor shown in FIG. 1, and FIG. 3 is shown in FIG. FIG. 4 is a block diagram schematically showing the structure of a conventional fan sensor, and FIG. 5 is an explanatory diagram when the fan sensor is used in a turbo molecular pump. 1 ... Detection unit, 2 ... Comparison unit, 3 ... Integration circuit, 4 ...
First relay, 5 ... Timer, 6 ... Second relay.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Kiyoshi Narita 25, Saiin Oiwake-cho, Ukyo-ku, Kyoto-shi, Kyoto Prefecture Shimazu Corporation Gojo factory (72) Incorporated company Yasutaka Furuichi 25 Saiin-Oiwake-cho, Ukyo-ku, Kyoto-shi, Kyoto Address Incorporated company Shimadzu Gojo factory (72) Inventor Naoyuki Tamura 794 Azuma Higashitoyo, Kumamatsu City, Yamaguchi Prefecture Incorporated company Hitachi Ltd. Kasado factory (72) Hideyuki Yamamoto 794 Azuma Toyoi, Kumamatsu City, Yamaguchi Prefecture Stock company Hitachi Kasado factory (56) Reference JP 54-102513 (JP, A) JP 60-55877 (JP, A) JP 57-48086 (JP, A)

Claims (1)

[Scope of utility model registration request] 1. A detector for detecting rotation of blades of a fan motor, and a comparison for comparing a period of a pulse signal from the detector with a reference period predetermined corresponding to a reference rotational speed of the fan motor. Section, a timer that stops the comparison operation of the comparison section for a certain period of time after the motor is started, an integration circuit that integrates the comparison output given from the comparison section, and a normally closed circuit controlled by the output of the integration circuit. A first open relay of a normally open type that is connected in series with the relay contacts of the first relay and is driven by the power source of the main fan sensor. A fan sensor characterized in that