KR101571869B1 - Installation unit of TRO sensor using ball-valve - Google Patents

Abstract

In the present invention, a ball valve is connected to a main pipe through which ballast water flows, and a TRO sensor is inserted so as to pass through the valve body of the ball valve, so that the TRO sensor can be mounted and separated while preventing leakage of ballast water. More particularly, the present invention relates to a TRO sensor mounting unit using a ball valve, and more particularly, a sampling valve is provided at the lower end of the valve body of the ball valve to perform not only the sampling function of the ballast water but also the internal pressure adjustment function And a wrench groove is formed in the valve body of the ball valve, so that the ball valve using the spanner can be easily mounted and separated. In the lower part of the TRO sensor, Damage to the TRO sensor and unnecessary ballast due to misdirection of the locking point of the ball valve by forming an indication line to be externally displayed In the junction box at the upper end of the TRO sensor, a mounting indicator is provided in which the outlet formed at the lower tip of the TRO sensor when the TRO sensor is mounted is in tangential direction with respect to the flow direction of the ballast water. A detachable locking bolt is installed on the valve body to prevent the valve knob from being rotated while the TRO sensor is mounted. The TRO sensor To a TRO sensor mounting unit using a ball valve so as to prevent damage to the sensor.

Description

[0001] The present invention relates to a TRO sensor mounting unit using a ball valve,

In the present invention, a ball valve is connected to a main pipe through which ballast water flows, and a TRO sensor is inserted so as to pass through the valve body of the ball valve, so that the TRO sensor can be mounted and separated while preventing leakage of ballast water. To a TRO sensor mounting unit using a ball valve.

In general, ballast water is installed on both sides of the bottom of a ship so that the ship can be prevented from being out of balance when the cargo is unloaded from the vessel or when the vessel is operated in a state where the amount of cargo loaded on the vessel is very small. Means freshwater or seawater for buoyancy adjustment to be filled in the ballast tank.

Such ballast water contains various microorganisms such as pathogenic bacteria and plankton contained in freshwater or seawater filled with ballast water. Therefore, if it is discharged into the water of another region without any treatment, serious marine pollution And the destruction of ecosystems.

Based on the above circumstances, in 1996, in the United States, the law on national invasive species was enacted, requiring the management and control of ballast water by stipulating the exotic species as an intruder. In Australia, the quarantine law was revised, And carries out direct quarantine for it.

On the other hand, the International Maritime Organization (IMO) concluded an international agreement in February 2004, and from 2009, the ship was required to install the necessary equipment for the sterilization and purification treatment of ballast water sequentially. In case of violation, And to prohibit all ports from entering.

Accordingly, various techniques for sterilizing marine ballast water have recently been developed. Typical examples thereof include sterilization treatment of ballast water using ozone (O ₃ ) gas or ultraviolet (UV) And a sterilization treatment of the ballast water using the method.

A TRO sensor for measuring the TRO (Total Residual Oxidant) concentration of the treated ballast water is additionally applied to the disinfection of the ballast water using the electrolysis method. By using the TRO sensor, the electrolytic ballast water The degree of neutralization of the ballast water is determined by measuring the total residual oxidant concentration in the ballast water discharged from the treatment device.

The TRO sensor typically includes a flow cell into which a predetermined amount of water flows, and a flow sensor that is disposed inside the flow cell and measures and converts the concentration of the oxide based on the amount of electrons (voltage, current measurement) A flow sensor for measuring the flow rate of the water collected through the inlet; and a flow sensor for measuring the flow rate of the water through the inlet, wherein the flow rate sensor comprises: an electrochemical sensor; a water inlet and outlet connected to the flow cell; And corrects the TRO measured value according to the flow rate.

Accordingly, the TRO sensor is mounted on the main pipe through which the ballast water flows, and the lower tip portion of the TRO sensor having the inlet and outlet for receiving water is positioned inside the main pipe. On the upper side of the TRO sensor, The water inlet is provided on the bottom tip of the TRO sensor and the outlet of the water is provided on the side of the bottom tip of the TRO sensor so that the inlet and the outlet of the water source do not interfere with each other. / RTI >

However, when the TRO sensor itself is connected to the main pipe in a penetrating manner, there is a problem that the ballast water flowing in the main pipe leaks unnecessarily large amount during the mounting and detaching operation of the TRO sensor. To prevent this, 1, the TRO sensor 20 connects the valve body 11 of the ball valve 10 to the mounting boss 1a provided on the main pipe 1, A mounting unit of a type in which it is inserted in a penetrating manner is used.

When the TRO sensor 20 is mounted on the main pipe 1 using the ball valve 10 as described above, when the TRO sensor 20 is mounted, the lower end of the TRO sensor 20 is connected to the valve body 11 The TRO sensor 20 can be pushed in and attached to the inside of the upper end of the TRO sensor 20 while the ball valve 10 is opened. The ball valve 10 can be locked immediately after it is removed from the body 11 so that leakage of the ballast water generated from the main pipe 1 at the time of mounting and separating the TRO sensor 20 can be minimized.

However, the conventional TRO sensor 20 mounting unit using the ball valve 10 is required to take a predetermined number of samples from the main pipe 1 in accordance with necessity such as a calibration operation of the TRO sensor 20 A separate water intake hole is formed on the main pipe 1 or the sample water is taken out through the ball valve 10 in a state in which the TRO sensor 20 is detached. It is difficult to perform the hole processing of the ballast water. Therefore, taking the sample water through the ball valve 10 is troublesome to control the flow rate, so that a large amount of ballast water is discharged and leaked.

Particularly, when the TRO sensor 20 is detached from the ball valve 10 for maintenance of the TRO sensor 20, the TRO sensor 20 is operated in accordance with the residual pressure (abu 2 to 3.5 bar or vacuum) When the main pipe 1 is in a vacuum state, the separation operation of the TRO sensor 20 itself becomes impossible, and the internal pressure of the main pipe 1 In the case of positive pressure (about 2 to 3.5 bar), the TRO sensor 20 bounces strongly due to the internal pressure of the main pipe 1, causing not only damage or breakage of the sensor but also damage to the person.

In addition, when the ball valve 10 is mounted on the main pipe 1 or the ball valve 10 is separated from the main pipe 1, a spanner, for example, The coupling part 11a formed at the lower end of the valve body 11 is fastened to the mounting boss 1a of the main pipe 1 or the fastening part 11a is fastened to the mounting boss 1a, The body of the valve body 11 and the spanner are not properly engaged with each other, so that mounting and dismounting operations of the ball valve 10 are relatively complicated.

On the other hand, if the ball valve 10 is locked in advance before the TRO sensor 20 completely disengages from the valve body 11 of the ball valve 10 during the separation operation of the TRO sensor 20, Since it is impossible to visually confirm to what extent the TRO sensor 20 inserted into the valve body 11 has escaped, the locking operation of the ball valve 10 can be prevented There was a problem that it was difficult to perform at an appropriate time.

In other words, according to the locking of the ball valve 10 before the TRO sensor 20 comes out through the spherical valve body built in the ball valve 10, damage of the TRO sensor 20 by the valve body can be prevented The TRO sensor 20 is completely removed from the ball valve 10 due to the possibility of the erroneous operation and unnecessary leakage of ballast water occurs due to the ball valve 10 being locked. A situation in which the TRO sensor 20 is damaged due to an erroneous operation of the ball valve 10 due to an operator error occurs frequently.

In addition, since the TRO sensor 20 can accurately measure the ballast water through the water inlet and outlet provided in the lower tip 21 of the TRO sensor 20, Since the pump type impeller is provided, there is no problem in inflow of the ballast water through the inlet port. However, since a very small amount of exhausted water passing through the electrochemical sensor is discharged through the outlet port, the TRO sensor 20 ) And the accuracy of the measured value greatly depend on the measurement performance.

For example, when the outlet provided on the side surface of the lower tip 21 of the TRO sensor 20 faces the flow direction of the ballast water through the main pipe 1, the flow rate of the ballast water causes the electrochemical sensor The TRO sensor 20 is mounted so that the position of the outlet is in the tangential direction with respect to the flow direction of the ballast water in consideration of this point of view. However, in the conventional case, there is a problem that a separate guide line for mounting the TRO sensor 20 at the correct position can not be provided.

Korean Patent No. 10-0975566 Korean Patent No. 10-1303966

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a sampling valve at the lower end of the valve body of the ball valve to provide not only a sampling function for ballast water but also an internal pressure adjusting function And a wrench groove is formed in the valve body of the ball valve, so that it is possible to easily mount and separate the ball valve using the spanner. At the lower side of the TRO sensor, , The damage of the TRO sensor and the leakage of unnecessary ballast water due to misdirection of the lock timing of the ball valve are prevented. On the other hand, in the junction box at the top of the TRO sensor, when the TRO sensor is installed, Wherein the outlet port is formed in a tangential direction with respect to the flow direction of the ballast water, In order to enable the flow of a single water and the discharge of the water, it is possible to carry out precise measurement work through it. In addition, a detachable locking bolt which prevents the valve knob from rotating when the TRO sensor is mounted is assembled on the valve body, It is a technical object to provide a TRO sensor mounting unit using a ball valve so as to prevent damage to the TRO sensor.

According to an aspect of the present invention, there is provided a ball valve comprising: a ball valve connected to a main pipe through which ballast water flows, a TRO sensor inserted through a valve body of the ball valve, The tip portion of the TRO sensor protrudes above the valve body of the ball valve for connection with the junction box, and the inner circumferential surface of the valve body on the upper side of the valve body A TRO sensor mounting unit using a ball valve provided on a lower inner circumferential surface thereof with a sealing ring provided in close contact with a TRO sensor to prevent leakage of ballast water, the TRO sensor mounting unit comprising: a main pipe coupling portion provided at a lower end side of the valve body; A sampling hole passing through the valve body is formed at a position corresponding to the space between the sealing rings provided on the periphery, A sampling valve having a sampling function for flowing ballast water flowing along the pipe and an internal pressure adjusting function for separating the TRO sensor is connected to the lower peripheral edge of the TRO sensor and a TRO sensor is detached from the valve body of the ball valve And an indication line for indicating the time point of locking the ball valve at the time of operation is provided.

In addition, a rectangular, hexagonal, or octagonal wrench groove is formed on the upper side of the valve body of the ball valve. The TRO sensor has an inlet for receiving water and a TRO And a TRO sensor is mounted on the upper end of the junction box of the TRO sensor so that the outlet formed at the lower tip of the TRO sensor is tangential to the flow direction of the ballast water. Wherein a detachable locking bolt is installed on one side surface of the valve body of the ball valve to prevent the valve knob from rotating to a locked position in a state in which the TRO sensor is mounted on the valve body. do.

According to the present invention, when it is desired to obtain a predetermined number of samples from the main pipe in accordance with the necessity of a calibration operation of the TRO sensor, it is possible to perform separate hole processing in the main pipe or to separate the TRO sensor from the ball valve By using the sampling valve connected to the valve body of the ball valve, it is possible to easily and precisely collect the number of samples as much as the required water quantity without unnecessary leakage of the ballast water.

In particular, even when the TRO sensor is separated from the ball valve for maintenance of the TRO sensor, the sampling valve is opened to adjust the residual pressure (abu 2 to 3.5 bar or vacuum) inside the main pipe to the atmospheric pressure level in advance The TRO sensor can be separated, and the separation operation of the TRO sensor can be performed more easily and safely.

In addition, it is possible to precisely engage a conventional spanner or a specially manufactured spanner in accordance with the present invention in a rectangular, hexagonal, or octagonal spanner groove formed on the circumference of the valve body of the ball valve, The operation of mounting the ball valve on the main pipe or separating the ball valve from the main pipe can be performed more easily and easily.

On the other hand, in the process of extracting the TRO sensor from the valve body of the ball valve for separating the TRO sensor, a point of time when the indication line formed on the lower side of the TRO sensor is visually confirmed, that is, It is possible to safely lock the ball valve in accordance with the optimum timing immediately after the sphere valve body built in the valve comes out.

Accordingly, damage of the TRO sensor caused by locking the ball valve before the TRO sensor comes out through the spherical valve body built in the ball valve, and damage of the TRO sensor after the TRO sensor is completely removed due to the possibility of such a wrong operation. There is an effect of preventing unnecessary leakage of the ballast water generated by locking the valve and that the erroneous operation of locking the ball valve in the state that the TRO sensor is mounted and the damage side of the TRO sensor can be prevented by the locking bolt in advance to provide.

In addition, by providing a mounting indicator on the top surface of the junction box of the TRO sensor that can mount the TRO sensor in accordance with the optimum position such that the outlet formed on the side surface of the bottom tip of the TRO sensor is positioned in the tangential direction with respect to the flow direction of the ballast water , The smooth flow of the ballast water through the TRO sensor, and the accuracy of the measurement operation based on the smooth flow of the ballast water can be ensured.

1 is a partially cutaway side view showing a conventional TRO sensor mounting unit using a ball valve;
2 is a partially cutaway side view showing a TRO sensor mounting unit of the present invention using a ball valve;
FIG. 3 is a partial cut-away side view of the ball valve and the TRO sensor in FIG. 2; FIG.
4 is a side cross-sectional view of a ball valve used in the present invention.
5 is a cross-sectional side view of a part of the TRO sensor used in the present invention.
6 is a schematic diagram showing an optimal arrangement of an outlet provided at the lower tip of the TRO sensor;
7 is a plan view of a junction box for a TRO sensor used in the present invention.
FIGS. 8A and 8B are a side view and a front view, respectively, of a main part showing a rotation preventing structure of a valve knob for a ball valve. FIG.
9 is an exemplary view of a ball valve spanner used in the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 2, the TRO sensor mounting unit using the ball valve according to the present invention also includes a ball valve 10 connected to a mounting boss 1a on a main pipe 1 through which ballast water flows, The TRO sensor 20 is inserted through the valve body 11 of the valve 10 and the lower tip portion 21 of the TRO sensor 20 is inserted into the valve body 11 of the ball valve 10 And the upper end side of the TRO sensor 20 protrudes above the valve body 11 of the ball valve 10 for connection with the junction box 22.

3 and 4, the ball valve 10 has a spherical valve body 15 inserted into the valve body 11, A valve seat (15a) is provided on the inner peripheral surface of the valve body (11) corresponding to the upper end side and the lower end side of the body (15) to support the rotation operation of the valve body (15) while preventing leakage of the ballast water. A valve shaft 16 for rotating the valve body 15 is connected to one side (right side in the drawing) of the valve body 11 and a valve knob 12 for providing a lever- .

The valve knob 12 is connected and fixed to one end (the right end in FIG. 4) of the valve shaft 16 by a knob assembly bolt 16a, and the other end of the valve shaft 16 An assembly shaft 16b for assembly with the valve body 15 is formed and an assembly shaft 16b of the valve shaft 16 is inserted into one side (right side in FIG. 4) of the valve body 15 A pair of sealing rings 18 are provided on the upper and lower inner circumferential surfaces of the valve body 11 so as to be in close contact with the TRO sensor 20 to prevent leakage of the ballast water, , And a pair of sealing rings 18 are also applied to the valve shaft 16.

The lower end of the valve body 11 is assembled to the lower end cap 17 by allowing the valve body 15 to be pulled out of the valve body 11 to repair or maintain the ball valve 10, A sensor insertion passage 10a for mounting the TRO sensor 20 is provided through the valve body 11 including the lower end cap 17 and the valve body 15 and a valve including the lower end cap 17, The upper and lower sides of the body 11 are formed with fastening portions 11a for assembling the TRO sensor 20 and for mounting the ball valve 10, respectively.

3 and 5, the TRO sensor 20 is formed in the shape of a cylinder rod to be inserted along the sensor insertion passage 10a of the valve body 11, and the TRO sensor 20, A junction box 22 is assembled to the upper end of the TRO sensor 20 by means of an adapter 24. The junction box 22 of the adapter 24 is connected to the lower end of the TRO sensor 20, And a union nut 23 to be assembled with the fastening portion 11a on the upper end side of the valve body 11 of the ball valve 10 is connected to the lower end.

The junction box 22 functions to transmit the measured value from the TRO sensor 20 to an external monitor or the like as described in the related art. For this purpose, the lower end of the junction box 22 is connected The cable 25 is connected to the connecting end 25 on the upper side of the TRO sensor 20 by a plug 25a and cable glands 22a for cable connection are provided on both sides of the junction box 22 And a connecting portion 24a for threaded assembly of the adapter 24 is formed on the lower side of the connecting end portion 25. The upper end portion of the adapter 24 is connected to the lower portion of the junction box 22, .

As shown in Figs. 3 and 4, the first essential part of the present invention includes a coupling part 11a for the main pipe 1 provided at the lower end side of the valve body 11, A sampling hole 17a passing through the valve body 11 is formed at a position corresponding to the space between the sealing ring 18 provided in the peripheral portion and the sampling valve 13 is connected to the sampling hole 17a More precisely, the sampling hole 17a and the sampling valve 13 are applied to the lower end cap 17 of the valve body 11.

The reason why the sampling hole 17a is passed through between the lower end fastening portion 11a of the valve body 11 and the sealing ring 18 located directly above the lower end of the valve body 11 is as follows. The TRO sensor 20 is provided with a clearance between the inner circumferential surface of the valve body 11 and the outer circumferential surface of the TRO sensor 20 so that the ballast water can flow into the gap between the inner circumferential surface of the valve body 11 and the outer circumferential surface of the TRO sensor 20, This is because it is an optimal position for performing the sampling operation of the ballast water by using the ballast 13.

4, the sampling valve 13 includes a valve body 13a in which a discharge passage having an approximately "T" shape is formed and a valve body 13b at one side (right side in the figure) of the valve body 13a. And a coupling part 13c provided at the other end (left end in the figure) of the valve body 13a and fastened to the sampling hole 17a, A valve pin 13d inserted horizontally along the discharge passage of the valve body 13a is connected to the valve knob 13b with a sealing ring and the valve body 13a is connected to the valve pin 13d, An inlet port 13e communicating with the discharge passage of the discharge port 13a is formed.

In other words, the sampling valve 13 has a structure similar to that of a known needle valve (a valve in which a pin-shaped spindle moves and flows in the same shaped cylindrical passage) It is most preferable to apply a needle valve capable of finely adjusting the flow rate to the sampling valve 13 from the viewpoint that a small amount of ballast water is taken from the pipe 1 in a quantitative manner by the sample water.

However, not only the needle valve but also various types of valve structures other than the needle valve can be applied to the sampling valve 13, and the sampling valve 13 can be installed in the sampling hole 17a, Even if the sampling valve 13 is welded to the sampling hole 17a, the lower end cap 17 of the valve body 11 is separated together with the sampling valve 13, Repair, maintenance, or replacement work.

If the sampling valve 13 is installed in the valve body 11 of the ball valve 10 as described above, a certain amount of sample water can be taken from the main pipe 1, The sampling valve 13 connected to the valve body 11 of the ball valve 10 without performing separate hole processing on the main pipe 1 or separating the TRO sensor 20 from the ball valve 10 ), It is possible to easily and accurately obtain the number of samples as much as the required quantity (water amount) without undue leakage of the ballast water.

Particularly, even when the TRO sensor 20 is separated from the ball valve 10 for maintenance of the TRO sensor 20, the sampling valve 13 is opened prior to the separation operation of the TRO sensor 20, 1), the TRO sensor 20 can be separated after the residual pressure (abu 2 to 3.5 bar or vacuum) inside the TRO sensor 20 is adjusted to the atmospheric pressure level. It can be carried out easily and safely.

As shown in FIGS. 3 and 4, the ball valve 10 may have a square, hexagonal, or octagonal shape in which a spanner can be mounted on the upper side of the valve body 11 And the wrench groove 11b may be formed in accordance with the dimensions of a generally used hexagon nut or octagonal nut spanner, or may be formed as shown in Fig. 9, The spanner 27 may be separately manufactured and used.

As described above, the conventional spanner or the specially manufactured wrench 27 is precisely transferred to the square or hexagonal or octagonal spanner groove 11b formed on the body of the valve body 11 of the ball valve 10 The operation of mounting the ball valve 10 on the main pipe 1 by rotating the spanner with the valve body 11 or removing the ball valve 10 from the main pipe 1 It can be easily and easily performed.

3 and 5, when the TRO sensor 20 is separated from the valve body 11 of the ball valve 10, the ball valve 10 An indication line 20a for indicating the locking point of the TRO sensor 20 is formed on the lower outer circumference of the TRO sensor 20 and the indication line 20a is connected to a TRO sensor 20 ) Is pre-marked with a desired color using a solvent-resistant paint excellent in weather resistance and abrasion resistance or a synthetic resin paint excellent in strength of a coating film.

The position at which the indication line 20a is marked on the TRO sensor 20 is determined by the lower tip of the TRO sensor 20 in the process of extracting the TRO sensor 20 from the valve body 11 of the ball valve 10 21 is exposed to the outside through the upper end of the valve body 11 immediately after exiting the spherical valve body 15 built in the ball valve 10 and the application of the indication line 20a The ball valve 10 can be safely locked in advance in accordance with the time when the indication line 20a is visually confirmed during the separation operation of the TRO sensor 20. [

Therefore, damage of the TRO sensor 20 caused by locking the ball valve 10 before the TRO sensor 20 comes out through the spherical valve body 15 built in the ball valve 10, An unnecessary leakage of the ballast water caused by locking the ball valve 10 after the TRO sensor 20 is fully taken out before the ball valve 10 can be locked before the TRO sensor 20 is pulled out due to the possibility of erroneous operation .

6 and 7, the water inlet is formed on the bottom surface of the lower tip 21 of the TRO sensor 20, and the bottom tip of the TRO sensor 20 (21a) formed in the lower tip (21) of the TRO sensor (20) is tangential to the flow direction of the ballast water under the condition that the outlet port (21a) An installation indicator 26 indicating the mounting position of the TRO sensor 20 is provided on the top surface 22b of the junction box 22 of the TRO sensor 20. [

The mounting indicator 26 is manufactured in the form of a thin metal plate, a plastic plate or a sticker in which an arrow line 26a indicating the flow direction of the ballast water is marked on the surface of the mounting indicator 26, 22 is completely assembled to the upper end of the TRO sensor 20 and then the position of the outlet 21a provided in the lower tip 21 of the TRO sensor 20 is checked so that the outlet 21a is connected to the mounting indicator 26, The mounting indicator 26 is fitted or attached to the upper end surface 22b of the junction box 22 such that the mounting indicator 26 is placed in the tangent direction with the arrow line 26a of the junction box 22.

The TRO sensor 20 to which the junction box 22 is connected is connected to the valve of the ball valve 10 in the state in which the mounting indicator 26 is assembled or attached to the upper surface 22b of the junction box 22 in the above- The arrow mark 26a of the mounting indicator 26 is placed in parallel with the installation direction of the main pipe 1 and then the union nut 23 of the TRO sensor 20 Is attached to the ball valve 10 by assembling the TRO sensor 20 with the fastening portion 11a formed at the upper end of the valve body 11 of the ball valve 10, 21 is placed in the tangential direction with respect to the flow direction of the ballast water through the main pipe 1 as shown in Fig.

The TRO sensor 20 can be mounted at an optimum position such that the outlet 21a formed in the side surface of the lower tip 21 of the TRO sensor 20 is positioned in the tangential direction with respect to the flow direction of the ballast water. It is possible to ensure the smooth flow of the ballast water through the TRO sensor 20 and the accuracy of the measurement operation on the basis of the smooth flow of the ballast water through the TRO sensor 20 by providing the water tank 26 on the top surface 22a of the junction box 22 of the TRO sensor 20. [ will be.

As a reference, the union nut 23 can be rotated relative to the adapter 24 in a state in which it is caught on the lower stage step of the adapter 24 connecting and fixing the junction box 22 with the TRO sensor 20 The TRO sensor 20 including the junction box 22 and the outlet 21a itself does not rotate together with the union nut 23 when the TRO sensor 20 is mounted using the union nut 23, The setting position of the outlet 21a based on the arrow line 26a of the mounting indicator 26 is not changed during the assembling process of the union nut 23. [

8A and 8B show a state in which the locking bolt 14 is assembled to one side (the right side in the figure) of the valve body 11 of the ball valve 10, The locking bolt 14 functions to prevent the valve knob 12 from being rotated to the locked position while the TRO sensor 20 is mounted. The valve knob 12 is not rotated in the locking direction of the ball valve 10, that is, in the clockwise direction in the figure, with the valve knob 12 placed in the open position of the ball valve 10, The lower end side engaging end portion 12b of the valve body 11 is engaged.

The TRO sensor 20 can be prevented from being damaged by the locking bolt 14 and the TRO sensor 20 can be prevented from being damaged by the mistake of locking the ball valve 10 in the state where the TRO sensor 20 is mounted, The locking bolt 14 is loosened from the valve body 11 and a separate connecting wire 14a is provided to prevent the loss of the locking bolt 14. [ It is preferable to suspend the locking bolt 14 on the valve knob 12 by using the locking knob 12 and the locking interlocking pin 12a shown in FIG. ) To limit the rotation angle of the valve knob 12 to 90 degrees.

In the above description, the TRO sensor 20 is mounted using the ball valve 10 on the main pipe 1 through which the ballast water for the ship flows. However, in the TRO sensor mounting unit using the ball valve according to the present invention, The present invention can be applied to various other types of sensor mechanisms for analyzing various components contained in the fluid by inserting the sensor means into the inside of the piping to which the present invention is to be applied. In the first place.

1: main pipe 1a: mounting boss 10: ball valve
10a: Sensor insertion passage 11, 13a: Valve body 11a, 13c, 24a:
11b: spanner groove 12, 13b: valve knob 12a: rotation interrupting pin
12b: latching end 13: sampling valve 13d: valve pin
13e: inlet 14: locking bolt 14a: connecting wire
15: valve body 15a: valve seat 15b: shaft assembly groove
16: Valve shaft 16a: Knob assembly bolt 16b: Assembly shaft
17: lower cap 17a: sampling groove 18: sealing ring
20: TRO sensor 20a: indication line 21: bottom tip
21a: outlet 22: junction box 22a: cable gland
22b: upper surface 23: union nut 24: adapter
25: connecting end 25a: connecting plug 26: mounting indicator
26a: arrow line 27: a spanner

Claims (5)

A ball valve 10 is connected to the main pipe 1 through which the ballast water flows and a TRO sensor 20 is inserted through the valve body 11 of the ball valve 10 and the TRO sensor 20 is inserted into the main pipe 1 through the valve body 11 of the ball valve 10 and the upper end of the TRO sensor 20 is connected to the junction box 22 The TRO sensor 20 is in close contact with the upper and lower inner circumferential surfaces of the valve body 11 of the ball valve 10 to prevent leakage of the ballast water. Wherein the sealing ring (18)
A valve body 11 is provided at a position between a fastening portion 11a for the main pipe 1 provided at the lower end side of the valve body 11 and a sealing ring 18 provided at the lower inner peripheral portion of the valve body 11, A sampling hole 17a is formed through the through-
A sampling valve 13 having a sampling function for flowing ballast water flowing along the main pipe 1 and an internal pressure adjusting function for separating the TRO sensor 20 is connected to the sampling hole 17a,
An indication line for indicating the locking time point of the ball valve 10 to the outside in an operation of separating the TRO sensor 20 from the valve body 11 of the ball valve 10 is provided on the lower outer circumferential edge of the TRO sensor 20 (20a) is provided to the TRO sensor mounting unit. The ball valve according to claim 1, wherein a wrench (11b) having a square, hexagonal or octagonal shape capable of mounting a spanner is formed on an upper peripheral edge of the valve body (11) of the ball valve Sensor mounting unit. delete The TRO sensor according to claim 1 or 2, wherein a water inlet is formed on the bottom surface of the bottom tip (21) of the TRO sensor (20) An outlet 21a of the first chamber 21a is formed,
A TRO sensor 20 is mounted on the upper end surface 22b of the junction box 22 of the TRO sensor 20 such that an outlet 21a formed in the lower tip 21 of the TRO sensor 20 is tangential to the flow direction of the ballast water. And a mounting indicator (26) indicating the mounting position of the TRO sensor mounting unit (26). The tilt sensor according to claim 1 or 2, wherein the valve body (11) of the ball valve (10) has a detachable / detachable structure for preventing the valve knob (12) And a locking bolt (14) is installed on the TRO sensor mounting unit.

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