JP2016044742A - Installation structure of steam trap - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an installation structure of a steam trap capable of accurately performing transmission operation with a transmitter while preventing submergence.SOLUTION: In an installation structure 10 of a steam trap 11, a sensor 21 for detecting temperature and vibration of the steam trap 11 is fixed to the steam trap 11, and a wireless transmitter 25 transmitting a signal on a detection value of the sensor 21 is connected to the sensor 21 with a signal line 22. Then, the installation structure 10 of the steam trap 11 is installed on the ground, and includes one installation base 40 in which the steam trap 11 and the transmitter 25 are installed separately.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a steam trap installation structure provided with a sensor and a transmitter.

  For example, as disclosed in Patent Document 1, a steam trap provided with a sensor and a transmitter (electronic analyzer) is known. In this steam trap, the temperature of the steam trap is detected by a sensor, and a signal related to the detected value is transmitted from the transmitter to another receiver. Thus, the temperature of the steam trap is monitored remotely.

JP-T-2001-500952

  By the way, in order to avoid submergence due to rain or the like, the steam trap as disclosed in the above-mentioned Patent Document 1 is not placed directly on the ground, but is fixed on a table and placed at a distance from the ground. It is known. This is because when the steam trap is submerged, it becomes difficult to accurately detect the temperature of the steam trap.

  However, in the above-described steam trap installation structure, the position of the center of gravity of the entire steam trap becomes high, and the posture of the entire steam trap becomes unstable. That is, in the steam trap disclosed in Patent Document 1 above, the sensor and the transmitter are connected and fixed in order from the bottom at the top, so that the center of gravity position is increased by being placed on the stand, and the posture Becomes unstable. In particular, the attitude of the transmitter located at the top becomes unstable. For this reason, the polarization plane of the radio wave transmitted from the transmitter changes, and transmission may not be performed accurately. That is, if the plane of polarization of the radio wave from the transmitter changes, the radio wave of the transmitter cannot be accurately received at the receiver.

  This invention is made | formed in view of this situation, The objective is to provide the installation structure of the steam trap which can perform the transmission operation | movement by a transmitter correctly, preventing submergence.

  The present invention is directed to a steam trap installation structure in which a sensor that detects at least one of temperature and vibration of a steam trap and a wireless transmitter that transmits a signal related to a detection value of the sensor are provided. The sensor is fixed in contact with the steam trap, and the transmitter is connected to the sensor by a signal line. Furthermore, this invention is equipped with one installation stand mounted on the ground and in which the said steam trap and the said transmitter are installed separately.

  According to the present invention, since the steam trap including the sensor and the transmitter is installed on the installation base, it is possible to prevent the steam trap from being submerged. Furthermore, according to the present invention, the sensor and the transmitter are connected by a signal line, and the steam trap and the transmitter are separately installed (fixed) on one installation stand, so that the attitude of the transmitter is stabilized. be able to. Therefore, the plane of polarization of the radio wave of the transmitter can be kept constant. As described above, it is possible to accurately perform the transmission operation by the transmitter while preventing the steam trap from being submerged.

FIG. 1 is a piping system diagram illustrating a schematic configuration of a steam system according to an embodiment. FIG. 2 is a side view schematically showing the installation structure of the steam trap and the transmitter according to the embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

  A steam system 1 according to the present embodiment shown in FIG. 1 heats an object (for example, a reaction kettle) with steam (saturated steam), and includes an installation structure of a steam trap 11 according to the present invention. In addition, the steam system 1 shown here is an example as what is provided with the installation structure of the steam trap 11 which concerns on this invention. The steam system 1 includes a steam generation unit 2, a plurality (six in this embodiment) of steam use systems, and a drain collection unit 4.

  The steam generating unit 2 generates water (saturated steam) by heating water. Each of the six steam use systems has a heat exchanger 3 and a steam trap 11. The steam generation unit 2 is connected to six steam use systems via a supply basket 5. That is, the supply rod 5 is branched into six and connected to the steam use system. Note that the number of steam use systems described above is merely an example, and the present invention only needs to have two or more steam use systems.

  In each steam use system, the heat exchanger 3 has an inlet connected to the steam generator 2 via a supply rod 5. In the heat exchanger 3, the steam supplied from the steam generation unit 2 dissipates heat to the object and condenses, and the object is heated. The steam becomes drain (condensate) by condensing. That is, the heat exchanger 3 is a latent heat exchanger that heats an object by latent heat of condensation of the vapor (latent heat heating). The outlet part is connected to the inlet part of the steam trap 11 via the outflow pipe 12.

  The steam trap 11 has an inlet connected to the outlet of the heat exchanger 3 through the inflow pipe 6 and an outlet connected to the drain collecting section 4 through the outflow pipe 7. The steam trap 11 is for drainage (condensate) generated by condensation of steam in the heat exchanger 3 or drainage mixed with steam (condensate) and automatically discharging only the drained drain from the outlet. is there.

  The drain collecting portion 4 is a relatively elongated tubular container, and is connected to each of the six steam usage systems. The drain collecting unit 4 collects the drain discharged from the steam trap 11 in each steam use system. A drain discharge pipe 8 through which drain is discharged is connected to the bottom of the drain collecting portion 4. Actually, in the drain collecting portion 4, part of the drain is evaporated to become steam, and the steam is discharged together with the drain to the drain discharge pipe 8.

<Installation structure of steam trap>
The above-described installation structure 10 of each steam trap 11 (hereinafter simply referred to as the installation structure 10) will be described with reference to FIG. The installation structure 10 includes one steam trap 11 and one installation table 40. FIG. 2 is a view from the outflow pipe 7 side.

  The steam trap 11 is provided with a sensor 21 and a transmitter 25. The sensor 21 detects both the temperature and vibration of the steam trap 11. The sensor 21 may detect only one of the temperature and vibration of the steam trap 11. The transmitter 25 is a wireless type that receives the detection value (detection temperature and detection vibration) of the sensor 21 and transmits a signal related to the detection value to a receiver (not shown).

  The installation table 40 is placed on the ground, and the steam trap 11 and the transmitter 25 are installed separately. Specifically, the installation base 40 includes a seat plate 41, a plurality of legs 43, and a standing plate 44. The seat plate 41 is disposed horizontally, and a leg 43 is provided on the lower surface of the seat plate 41. The leg 43 is formed in a rod shape and is in contact with the ground. The standing plate 44 is provided on the outer edge of the seating surface 42 (upper surface) of the seating plate 41. The standing plate 44 is erected vertically with respect to the seat plate 41.

  The steam trap 11, the sensor 21, and the transmitter 25 are installed on the installation table 40. The steam trap 11 is placed on the seat plate 41 of the installation base 40 (on the seat surface 42). The steam trap 11 is fixed to the seat plate 41 with bolts or the like with the side surface 15 in contact with the front surface 45 of the upright plate 44. As described above, the outlet pipe 7 is connected to the outlet portion 12 of the steam trap 11.

  The sensor 21 is formed in a substantially rod shape (substantially cylindrical shape), and the tip (lower end in FIG. 2) is fixed in contact with the upper surface 13 of the steam trap 11. Specifically, the installation structure 10 is provided with a sensor fixture 23 for fixing the sensor 21 to the steam trap 11. The sensor fixture 23 is, for example, a plate-like member, and one end (right end portion in FIG. 2) is supported by the upper portion of the standing plate 44 in the installation base 40, and the other end (left end portion in FIG. 2) is the sensor 21. Is attached. The sensor fixture 23 presses and fixes the sensor 21 from above the steam trap 11 to the upper surface of the steam trap 11. That is, the sensor 21 is arranged in a state of being substantially vertical on the upper surface 13 of the steam trap 11.

  The transmitter 25 is connected to the sensor 21 by a signal line 22. The transmitter 25 is installed (fixed) at a location different from the steam trap 11 on the installation table 40. Specifically, the transmitter 25 is fixed to the back surface 46 of the standing plate 44 in the installation base 40 with bolts or the like. An antenna 26 that emits radio waves toward the receiver is provided above the transmitter 25. In the present embodiment, the transmitter 25 is installed at substantially the same height as the steam trap 11.

  In the installation structure 10 described above, the temperature and vibration of the steam trap 11 are detected by the tip of the sensor 21, and the detected value is sent to the transmitter 25 via the signal line 22. In the transmitter 25, a signal related to the detection value sent from the sensor 21 is emitted from the antenna 26 as a radio wave. Radio waves from the transmitter 25 are received by the receiver, and the state (temperature and vibration) of the steam trap 11 is remotely monitored.

  As described above, according to the installation structure 10 of the above embodiment, the steam trap 11, the sensor 21, and the transmitter 25 are installed on the installation table 40. Thereby, since the steam trap 11, the sensor 21, and the transmitter 25 are installed at a distance from the ground, the steam trap 11 and the like can be prevented from being submerged by rain or the like. Therefore, the temperature and vibration of the steam trap 11 can be accurately detected by the sensor 21.

  Furthermore, according to the installation structure 10 of the above embodiment, the sensor 21 and the transmitter 25 are connected by the signal line 22, and the steam trap 11 and the transmitter 25 are separately installed (fixed) on one installation table 40. I did it. Thereby, since the transmitter 25 can be reliably fixed to the installation base 40, the attitude | position of the transmitter 25 can be stabilized. Therefore, the plane of polarization of the radio wave emitted from the antenna 26 of the transmitter 25 can be kept constant. Thus, radio waves can be accurately transmitted from the transmitter 25 to the receiver. As described above, according to the embodiment, it is possible to provide the installation structure 10 of the steam trap 11 that can accurately perform the transmission operation by the transmitter 25 while preventing the steam trap 11 from being submerged.

  Moreover, in the installation structure 10 of the said embodiment, the sensor fixture 23 which presses and fixes the sensor 21 to the upper surface 13 of this steam trap 11 from the upper direction of the steam trap 11 was provided. Therefore, the steam trap 11 is pressed against the seat plate 41 of the installation base 40 by the pressing action of the sensor fixture 23. Thereby, the steam trap 11 can be more reliably fixed to the seat plate 41, and the posture of the steam trap 11 can be maintained more stably. Therefore, the temperature and vibration of the steam trap 11 can be detected more accurately by the sensor 21.

  Moreover, in the installation structure 10 of the said embodiment, since the steam trap 11 was installed in the seat board 41 and the transmitter 25 was installed in the back surface 46 of the standing board 44 in the installation stand 40, the weight balance of the installation structure 10 whole is made. Can be better. Therefore, the postures of the steam trap 11 and the transmitter 25 can be further stabilized.

  In addition, in the installation structure 10 of the said embodiment, although the installation base 40 was formed in chair shape, the installation base 40 which concerns on this invention installs the steam trap 11 and the transmitter 25 at a distance from the ground, and is a steam trap. Any shape may be employed as long as the transmitter 11 and the transmitter 25 can be installed at different locations.

  Moreover, in the installation structure 10 of the said embodiment, the fixing methods of the steam trap 11 and the transmitter 25 may be any methods as long as they can be fixed to the installation table 40, respectively. The sensor 21 may be fixed by any method as long as the tip of the sensor 21 can be fixed in contact with the steam trap 11.

  The present invention is useful for an installation structure of a steam trap provided with a sensor and a transmitter.

DESCRIPTION OF SYMBOLS 10 Steam trap installation structure 11 Steam trap 13 Upper surface 21 Sensor 22 Signal line 23 Sensor fixture 25 Transmitter 40 Installation stand 41 Seat plate

Claims (2)

A steam trap installation structure in which a sensor that detects at least one of temperature and vibration of the steam trap and a wireless transmitter that transmits a signal related to a detection value of the sensor are provided,
The sensor is fixed in contact with the steam trap,
While the transmitter is connected to the sensor by a signal line,
An installation structure of a steam trap, which is placed on the ground and includes one installation table on which the steam trap and the transmitter are installed separately. In the installation structure of the steam trap according to claim 1,
While the installation table is horizontally disposed and has a seat plate on which the steam trap is placed,
A steam trap installation structure comprising a sensor fixture that is supported by the installation table and that presses and fixes the sensor from above the steam trap against the upper surface of the steam trap.

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