JP6657926B2 - Temperature measuring device - Google Patents

Description

  The present invention relates to a temperature measuring device suitable for measuring an industrial device which easily vibrates during operation, and more particularly to a temperature measuring device suitable for measuring a temperature of a bearing which supports a separator of a vertical crusher.

In order to keep the operation of the industrial apparatus in a stable state, it is important to monitor the temperature and to continuously control the operation conditions so as not to deviate from an appropriate temperature range.
In particular, for an industrial apparatus such as a vertical crusher having a rotating part, it is important to monitor the temperature near the rotating part. For example, if the temperature of the rotating part changes rapidly, abnormalities such as damage to the bearings supporting the rotating part and poor lubrication are suspected. The temperature abnormality is also a measure for detecting an abnormality of the device. It is also possible to predict the life of the equipment by logging an analog electric signal (sometimes referred to as an analog electric signal) over a long period of time and monitoring a temperature trend.

Conventionally, the temperature of an industrial device has been generally measured using a thermocouple, a resistance temperature detector, or the like. If a thermocouple, a resistance thermometer or the like is used, the result of the temperature measurement can be output to the outside as an analog electric signal.
As another temperature measurement method, for example, a method of measuring the temperature of an industrial device using a liquid-filled pressure-type thermometer is known. The liquid-filled pressure-type thermometer has a disadvantage that it cannot output an electric signal or the like, but has an excellent merit that a power source is not required and the temperature can be easily checked on site by displaying a needle of the thermometer.

The liquid-filled pressure-type thermometer generally includes a temperature-sensitive cylinder, a conduit, and a temperature display. The temperature-sensitive cylinder is filled with a liquid sensitive to temperature. When the temperature-sensitive cylinder is brought into contact with a measurement location, the filled liquid undergoes thermal expansion or thermal contraction and changes in pressure.
The change in the pressure of the liquid in the temperature-sensitive tube section is transmitted to a Bourdon tube arranged in the temperature display section through a conduit. A rotating shaft for rotating the temperature indicating needle is attached to the Bourdon tube, and the temperature is transmitted to a needle of a thermometer (sometimes referred to as a temperature indicating needle) to display the temperature.

  Patent Document 1 discloses a temperature measuring device that includes a thermocouple and a liquid-filled pressure-type thermometer in combination.

JP-A-11-51777

  The composite temperature sensor disclosed in Patent Literature 1 focuses on a weak point of a liquid-filled pressure-type thermometer in that an electric signal cannot be output, and uses a thermocouple in order to compensate for it.

  In order to control the temperature of an industrial device, it is desired not only to visually check the needle of a thermometer but also to output a measurement result as an electric signal that can be transmitted to a control device or the like in real time or automatically. In that respect, the technology disclosed in Patent Document 1 is expected to produce an effect.

However, when a thermocouple is used for measuring the temperature of the vibrating body, there is a risk that a problem such as breakage of a wire of the thermocouple due to vibration may occur.
In particular, in the case where the temperature near the rotating portion is measured by a thermocouple, the thermocouple serving as a sensor is constantly exposed to vibration. For this reason, there is a possibility that the element wire of the thermocouple serving as a sensor is easily broken, and the life of the temperature measuring device is shortened.
Similarly, in the case of measuring the temperature in the vicinity of the rotating part with a resistance temperature detector, the resistance temperature sensor serving as a sensor is always exposed to vibration and is easily damaged, which may cause a problem of shortening the service life. was there.

  For example, in a vertical pulverizer in which a separator is provided in an apparatus, a bearing for rotatably supporting a rotating cylinder of the separator is generally provided at an upper portion. For smooth operation of the vertical crusher, it is an important factor to monitor the temperature of the bearing and take appropriate action promptly if necessary.

  Conventionally, the temperature of a bearing that supports a rotating cylinder of a separator has been measured by using a thermocouple or a temperature measuring resistor as a sensor. However, as described above, there is a problem that a thermocouple or a resistance temperature detector is easily damaged when constantly exposed to vibration.

  The present invention has been made in view of the problems as described above, and relates to a temperature measuring device suitable for measuring an industrial device which easily vibrates during operation, and particularly to a bearing used for a separator of a vertical crusher. A temperature measuring device suitable for measuring the temperature of the

In order to achieve the above object, a temperature measuring device according to the present invention comprises:
(1) A liquid-filled pressure-type thermometer and a rotary potentiometer that detect a pressure change due to the temperature of the enclosure in the temperature-sensitive cylinder and measure the temperature,
By detecting the rotation angle of the measured value output shaft of the thermometer with a potentiometer and outputting it as an electric signal, the separator provided in a vertical crusher that crushes the raw material supplied on the rotary table with crushing rollers. A temperature measuring device for measuring the temperature of a bearing that supports a rotating shaft, wherein grease is filled in a gap between the thermosensitive cylinder and the bearing.

(2) The temperature measuring device according to (1), wherein a rotation angle of the measurement value output shaft is measured by a potentiometer by connecting a measurement value output shaft of the thermometer and an input shaft of a potentiometer. To detect.

(3) The temperature measuring device according to (1) or (2), wherein a liquid is filled in a space in which a measured value output shaft of the thermometer and a temperature display needle are provided, and the temperature display needle is rapidly rotated. Relax.

(4) The temperature measuring device according to any one of (1) to (3), wherein the electric signal is subjected to an electric filter process as an analog electric signal.

  ADVANTAGE OF THE INVENTION According to the temperature measuring device by this invention, when measuring the temperature of the industrial apparatus with a large vibration, the outstanding effect that a measured value can be output to an external part quickly by an analog electric signal, and it is hard to be damaged even if it receives a vibration. It works.

It is a figure explaining the attachment situation of the vibrating body temperature measuring device concerning an embodiment of the present invention. It is a figure explaining composition of a vibrating body temperature measuring device concerning an embodiment of the present invention. It is a figure explaining the situation at the time of attaching a vibrating body temperature measuring device to a vertical crusher concerning an embodiment of the present invention. It is a figure explaining a main part of a vibrating body temperature measuring device concerning an embodiment of the present invention. It is a figure explaining the main part of the vibrating body temperature measuring device concerning other embodiments of the present invention. FIG. 3 is a reference diagram for explaining the configuration of a potentiometer and a temperature indicator.

Hereinafter, examples of preferred embodiments of the present invention will be described in detail with reference to the drawings and the like.
FIGS. 1 to 5 relate to the drawings for explaining the embodiments of the present invention, and show preferred examples thereof. FIG. 1 is a diagram illustrating a state of attachment of the vibrating body temperature measuring device, and FIG. 2 is a diagram illustrating a configuration of the vibrating body temperature measuring device. FIG. 3 is a view for explaining a situation when a vibrating body temperature measuring device is attached to a vertical grinder. FIG. 4 is a diagram illustrating a main body of the vibrating body temperature measuring device, and FIG. 5 is a diagram illustrating another embodiment of the vibrating body temperature measuring device. FIG. 6 is a reference diagram illustrating the configuration of a potentiometer and a temperature indicator.

1 and 2 show a configuration of a vibrating body temperature measuring device 10 (sometimes abbreviated as a temperature measuring device 10) according to an embodiment of the present invention.
The temperature measuring device 10 includes a main body 1 and a sensor 2, and the main body 1 and the sensor 2 are connected by a conduit 8C.

  FIG. 4 shows the configuration of the main body 1. FIG. 4 is a diagram for explaining a connection structure between the liquid-filled pressure-type thermometer 8 and the potentiometer 5 shown in the reference diagram of FIG. 6, and a cross-sectional view of the connection case 13 portion.

As shown in FIG. 4, the main body 1 of the temperature measuring device 10 includes a temperature display case 8B of a liquid-filled pressure-type thermometer 8 (sometimes abbreviated as a hydraulic thermometer 8) and a potentiometer. 5 is integrated by a connection case 13.
Then, the measured value output shaft 8A (sometimes referred to as the output shaft 8A) on the display portion 8D side of the hydraulic thermometer 8 and the input shaft 5A of the potentiometer 5 are connected by the rotating shaft connecting portion 11.

  At this time, it is preferable that the space in which the temperature indicating needle 8F is disposed by the connection case 13 is filled with a liquid such as oil. During operation, even if the temperature display needle 8F suddenly rotates and shakes due to vibration, there is a possibility that rapid rotation of the temperature display needle 8F can be suppressed due to the viscosity of the filled oil. Therefore, it can be expected that the influence on the electric signal to the control device described later is minimized.

Here, the configuration of the hydraulic thermometer 8 used in the present embodiment will be briefly described. FIG. 2 shows the configuration of the hydraulic thermometer 8.
The hydraulic thermometer 8 includes a temperature-sensitive cylinder section 8E, a conduit section 8C, a temperature display case section 8B, and the like. A Bourdon tube (not shown) is arranged inside the temperature display case portion 8B, and a conduit portion 8C is connected to the Bourdon tube.
On the temperature display section 8D side, there are provided an output shaft 8A connected to the Bourdon tube, and a temperature display hand 8F attached to the output shaft 8A.

  In addition, the inside of the temperature-sensitive tube portion 8E, the conduit portion 8C, and the Bourdon tube is filled with an organic liquid. When the liquid filled in the temperature-sensitive tube portion 8E expands or contracts due to a change in temperature, the pressure of the liquid filled in the Bourdon tube changes via the conduit 8C. When the pressure of the liquid filled in the Bourdon tube changes, the tip of the Bourdon tube is displaced. As a result, the output shaft 8A connected to the Bourdon tube rotates and the temperature display needle 8F rotates to display the temperature. .

In the above-described embodiment, an example has been described in which the Bourdon tube is disposed inside the temperature display case portion 8B and the temperature is displayed by displacement of the Bourdon tube tip.
However, the configuration of the hydraulic thermometer 8 applicable to the present invention is not limited to this, and can be changed without departing from the technical idea of the present invention.
For example, a method may be used in which an expandable and contractable bellows is arranged inside the temperature display case section 8B, and the temperature is displayed by a change in the amount of expansion and contraction of the bellows due to a change in the pressure of the liquid.

Next, the potentiometer 5 used in the present embodiment will be briefly described.
The potentiometer 5 used in the present embodiment includes a resistance portion and the like inside, and detects a change in the rotation angle of the input shaft 5A based on a change in resistance value with respect to the rotation of the input shaft 5A. Of the potentiometer 5.
The potentiometer 5 used in the present embodiment detects the rotation angle of the output shaft 8A on the temperature display section 8D side of the hydraulic thermometer 8 and controls the output not shown via an output code 10C. Output an electrical signal to the device.

  The electric signal at this time is preferably subjected to an electric filter process as an analog signal. During operation, even if the temperature display needle 8F suddenly rotates and shakes due to vibration, if it is processed as noise by performing electric filtering, the influence on the analog electric signal to the control device can be minimized. Can be expected.

  In the present embodiment, the sensor section 2 is constituted by the temperature-sensitive cylinder section 8E of the hydraulic thermometer 8 described above.

Hereinafter, the configuration of the vertical crusher 70 will be briefly described, and a method of arranging the temperature measuring device 10 and the like will be described.
The vertical crusher 70 shown in FIG. 3 includes an upper casing 81B, a lower casing 81A, a speed reducer 82B installed at a lower portion, a rotary table 72 driven by a drive motor 82M, a conical crush roller 73, and the like. I have.
The two crushing rollers 73 are arranged on the rotary table 72 so as to face the outer peripheral portion.

  In the vertical pulverizer 70, the raw material is supplied onto the rotary table 72 from a raw material supply port 85 formed at the upper part. The raw material supplied on the rotary table 72 is pulverized on the rotary table 72 by the pulverizing roller 73. The pulverized raw material is blown up by the gas introduced from the gas inlet 83, classified by a separator described later, and the one having a predetermined size is taken out as a product from the outlet 89.

The vertical pulverizer 70 shown in FIG. 3 is provided with a separator composed of a fixed primary classification blade 74 and a rotary rotary classification blade 76 at the upper part. The separator is sometimes referred to as a classification mechanism, and can selectively separate a raw material having a desired particle size.

The vertical crusher 70 shown in FIG. 3 has a structure in which a fixed primary classifying blade 74 is arranged on the outer peripheral side of a rotary classifying blade 76, and an internal cone 79 is arranged below the fixed primary classifying blade 74. . The fixed primary classifying blades 74 are generally referred to as guide vanes, and the rotary rotating classifying blades 76 are generally referred to as rotating vanes.

  In the present embodiment, a classification mechanism having a two-stage configuration of the primary classification blade 74 and the rotary classification blade 76 is adopted. However, the configuration of the classification mechanism applicable to the present invention is not limited to this, and the present invention is not limited thereto. For example, a separator having only a rotary classifying blade 76 may be used.

Here, as shown in FIGS. 1 to 3, the rotary classifying blades 76 are attached to the separator rotating cylinder 21, and a belt pulley 27 is attached to the upper part of the separator rotating cylinder 21. A belt (not shown) is attached to the belt pulley 27.

In addition, as shown in FIG. 1, the separator rotary cylinder 21 is attached to the upper part of the vertical crusher 70 via the upper bearing 25 and the lower bearing 23.
The above-mentioned belt applied to the belt pulley 27 is driven by a drive motor (not shown) installed on the upper part of the vertical pulverizer 70, and is configured to rotate freely. Rotates, and the rotary classifying blade 74 rotates.

Here, in the present embodiment, as shown in FIGS. 1 and 2, the sensor section 2 of the temperature measuring device 10 is arranged on the side surface of the lower bearing 23 so that the temperature-sensitive cylinder section 8 </ b> E comes into contact.
At this time, grease G is filled between the lower bearing 23 and the temperature-sensitive cylinder 8E.

A control unit (not shown) in which the sensor unit 2 and the main unit 1 disposed outside the machine are connected by a conduit unit 8C and the measured value of the potentiometer 5 is externally disposed as an analog electric signal via an output code 10C. It is configured to transmit to.

During operation of the vertical pulverizer 70, the separator rotating cylinder 21 rotates while being supported by the upper bearing 25 and the lower bearing 23.
The liquid filled in the temperature-sensitive tube portion 8E brought into contact with the lower bearing 23 expands or contracts due to a change in the temperature of the lower bearing.
The change in the volume of the liquid filled in the temperature-sensitive tube portion 8E affects the liquid filled in the Bourdon tube disposed inside the temperature display case portion 8B via the conduit 8C, and the liquid filled in the Bourdon tube. Pressure changes. As a result, the tip of the Bourdon tube is displaced, and the output shaft 8A connected to the Bourdon tube rotates.

When the output shaft 8A rotates, the input shaft 5A of the potentiometer 5 connected via the rotation shaft connecting portion 11 rotates.
As described above, the potentiometer 5 has a resistance portion and the like therein, and detects a change in the rotation angle of the input shaft 5A based on a change in resistance value with respect to the rotation of the input shaft 5A.
Then, the potentiometer 5 which has detected the rotation angle of the output shaft 8A outputs an analog electric signal to an externally provided control device (not shown) via the output code 10C.

According to the configuration of the present embodiment, the detected temperature can be output as an analog electric signal, and efficient control can be performed. For example, when the temperature of the bearing suddenly changes, abnormalities such as damage and poor lubrication are suspected. If the temperature measuring device 10 according to the present embodiment is used, a temperature abnormality of the lower bearing 23 is automatically detected by setting a value in a normal range in the control device, and is fed back to the operating conditions of the vertical mill 70. It becomes possible.
Further, as described above, if the tendency of the temperature is monitored by logging the analog electric signal for a long period of time, it is possible to predict the life of the lower bearing 23 and the like.

During operation of the vertical crusher 70, the separator rotating cylinder 21 rotates. At this time, vibration may occur due to the raw material to be classified colliding with the rotary classification blades 76. Also, when the crushing roller 73 crushes the raw material on the rotary table 72, vibration may occur.

According to the temperature measuring device 10 of the present embodiment, the liquid filled in the temperature-sensitive cylinder 8E serving as a sensor is not damaged by vibration. Therefore, unlike a thermocouple system using element wires for the sensor, the sensor is hardly damaged by vibration.

In the above-described embodiment, the temperature-sensitive cylinder portion 8E is configured to abut on the side surface of the lower bearing 23. However, a method may be used in which the temperature-sensitive tube portion 8E is not in direct contact with the side surface of the lower bearing 23, but is indirectly contacted with a viscous liquid having good heat conductivity such as grease G. . In this case, a slight gap is formed between the temperature-sensitive cylinder portion 8E and the side surface of the lower bearing 23. Therefore, even if the lower bearing 23 vibrates, the temperature-sensitive cylinder 8E and the lower bearing 23 do not directly come into strong contact with each other.

In particular, in the vertical crusher 70, the vibration cycle of the bearing due to the rotation of the separator rotary cylinder 21 does not often coincide with the vibration cycle of the entire vertical crusher 70.
When measuring the temperature of the bearing of the separator rotary cylinder 21, when the temperature-sensitive cylinder 8 E is directly brought into contact with the side surface of the lower bearing 23, the temperature-sensitive cylinder 8 E moves downward due to the difference in the vibration cycle. There is a possibility that the bearing 23 is strongly pressed against the bearing 23 unexpectedly.
However, in the embodiment in which the temperature-sensitive cylinder portion 8E is not closely contacted with the side surface of the lower bearing 23 but is slightly close to the gap, there is a margin for vibration by the distance of the gap, and it is strongly pressed. This is a particularly preferable configuration because the possibility is reduced.

As described above, according to the present embodiment, even if the temperature sensing tube portion 8E is constantly exposed to vibration, the possibility of damage is small and the risk of shortening the life can be reduced.

Further, in the vertical pulverizer 70, a stray current may rarely occur due to the influence of welding or the like. The stray current may become noise and adversely affect the electric signal.
The temperature measurement device 10 according to the present embodiment transmits a temperature change as a change in the pressure of the liquid from the sensor unit 2 to the main unit 1, and thus is not easily affected by the stray current.

  Hereinafter, as another embodiment of the present invention, an example of a system in which the configuration of the main body 1 is different will be described with reference to FIG.

The main body 1a shown in FIG. 5 has an output shaft 8H protruding from the rear side opposite to the temperature display case 8B of the hydraulic thermometer 8, and is connected to the potentiometer 5 by a rear connection case 13B. And integrated.
The main body 1a connects the output shaft 8H on the side opposite to the temperature display section of the hydraulic thermometer 8 to the input shaft 5A of the potentiometer 5 by the rotating shaft connecting portion 11B. When the pressure of the liquid filled in the Bourdon tube changes and the output shaft 8H rotates, the input shaft 5A rotates via the rotation shaft connecting portion 11B, and the temperature is displayed.

In the main body 1a, the rotation angle can be detected by the potentiometer 5 while visually checking the temperature display hand 8F of the hydraulic thermometer 8, and the measured value of the potentiometer 5 is determined by the output code 10C. Thus, the signal can be promptly transmitted as an analog electric signal to a control device (not shown) provided outside.

  The vibrating body temperature measuring device according to the present invention can quickly output a measured value with an analog electric signal when measuring temperature of an industrial device having large vibrations, and is less likely to damage the temperature-sensitive cylinder even when subjected to vibration. It has excellent effects.

DESCRIPTION OF SYMBOLS 1 Main part 1a Main part 2 Sensor part 5 Potentiometer 5A Input shaft 5B Potentiometer main part 5C Output code 8 Liquid-filled pressure-type thermometer (hydraulic-type thermometer)
8A Measurement value output axis (output axis)
8B Temperature display case part 8C Conduit part 8D Temperature display surface 8E Temperature sensing tube part 8F Temperature display needle 8H Output shaft (back side)
10 Vibration body temperature measuring device 11 Rotary shaft connecting part 11B Rotary shaft connecting part (back side)
13 Connection Case 13B Back Connection Case 21 Separator Rotating Cylinder 23 Lower Bearing 25 Upper Bearing 27 Belt Pulley 72 Rotary Table 73 Crushing Roller 85 Raw Material Supply Port 83 Gas Inlet 70 Vertical Crusher

Claims (4)

Equipped with a liquid-filled pressure-type thermometer and a rotary potentiometer that detects a pressure change due to the temperature of the enclosure in the temperature-sensitive cylinder and measures the temperature,
By detecting the rotation angle of the measured value output shaft of the thermometer with a potentiometer and outputting it as an electric signal, the separator provided in a vertical crusher that crushes the raw material supplied on the rotary table with crushing rollers. What is claimed is: 1. A temperature measuring device for measuring the temperature of a bearing that supports a rotating shaft, wherein grease is filled in a gap between the temperature-sensitive cylinder and the bearing .   The temperature measurement device according to claim 1, wherein a rotation angle of the measurement value output shaft is detected by a potentiometer by connecting a measurement value output shaft of the thermometer and an input shaft of a potentiometer.   The temperature measuring device according to claim 1, wherein the space in which the measured value output shaft of the thermometer and the temperature display needle are housed is filled with a liquid to reduce a sudden rotation of the temperature display needle.   The temperature measuring device according to any one of claims 1 to 3, wherein the electric signal is subjected to an electric filter process as an analog signal.

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