JP2014086530A - Moisture absorption respiratory - Google Patents

Abstract

Provided is a hygroscopic respirator capable of observing respiration of an oil-filled electrical device even when the respiration rate is relatively small or relatively large.
A hygroscopic respirator has a breathing valve having an inhalation part and an exhaust part, and a main body to which the breathing valve can be attached. The intake portion has a spherical intake portion float and an intake portion float receiving plate having an intake portion breathing hole for engaging the intake portion float, and the intake portion float and the intake portion breathing hole And a check valve for introducing air from the outside into the main body. The exhaust part is separated from the main body by a spherical exhaust part float, an exhaust part float receiving plate having an exhaust part breathing hole for engaging the exhaust part float, the exhaust part float and the exhaust breathing hole. A check valve for sending air to the outside is configured.
[Selection] Figure 1

Description

  The present invention relates to a hygroscopic respirator used for an oil-filled electrical device such as an oil-filled transformer, and more particularly to a breathing valve of the hygroscopic respirator.

  Oil-filled electrical devices such as oil-filled transformers include a tank that stores insulating oil. The tank is a sealed container so that the insulating oil does not deteriorate. Therefore, a pressure difference is generated between the pressure in the tank and the atmosphere due to a temperature change or the like. Therefore, an oil storage device (conservator) is provided in the tank. The oil storage unit is configured so that oil in the tank does not directly contact outside air and allows air to enter and exit.

  For example, in the morning when the temperature of the oil-filled electrical equipment rises, air is discharged from the inside of the tank to the outside via the oil storage, and in the evening when the temperature of the oil-filled electrical equipment falls, the oil storage equipment is used. Inhale air from the outside of the tank. This is called the “breathing action” of oil-filled electrical equipment.

  The breathing port of the oil storage device is provided with a dehydrating breather for removing the humidity of the inhaled air. A hygroscopic respirator usually uses silica gel as a hygroscopic agent. As the hygroscopic respirator, a wet type using an oil pot or seal oil and a so-called oilless type or dry type not using the oil pot are known. For example, Patent Document 1 describes an example of an oilless type hygroscopic respirator.

Japanese Patent Laid-Open No. 10-135043

  In the conventional so-called oilless type or dry type hygroscopic respirator, the “breathing action” of the oil-filled electrical device cannot be observed with the naked eye. That is, it has not been possible to visually observe whether the oil-filled electrical device is currently inhaling, exhaling air, or not breathing.

  An object of the present invention is to provide a hygroscopic respirator that can observe respiration of an oil-filled electrical device even if the respiration rate is relatively small or relatively large.

  The dry breathing valve of the hygroscopic respirator according to the present invention is attached to the hygroscopic respirator, and has a function of blocking moisture intrusion into the hygroscopic respirator to prevent waste of the hygroscopic agent during non-breathing. In addition, it has a function of displaying the breathing state during breathing.

According to the present invention, in a hygroscopic respirator having a breathing valve having an intake portion and an exhaust portion, and a main body to which the breathing valve can be attached,
The main body includes a top plate, a bottom body, a glass cylinder sandwiched between the top plate and the bottom body, a vent pipe provided in the glass cylinder, and a moisture absorbent filled in the glass cylinder. And the top plate is provided with a breathing valve connecting portion for connecting the breathing valve, and a breathing pipe connecting portion for connecting the vent pipe to a breathing pipe from an oil storage device, The intake section includes an intake section inlet for inhaling air from the outside, a spherical intake section float, and an intake section float receiving plate having an intake section breathing hole for engaging the intake section float; An intake portion outlet for discharging air to the main body, and a check valve for introducing air from the outside into the main body by the intake portion float and the intake portion breathing hole, The exhaust part includes an exhaust part inlet for introducing air from the main body, a ball The exhaust part float, an exhaust part float receiving plate having an exhaust part breathing hole for engaging the exhaust part float, and an exhaust part outlet for exhausting air to the outside, the exhaust part float The exhaust breathing hole constitutes a check valve for sending air from the main body to the outside.

  According to the embodiment of the present invention, in the hygroscopic respirator, the intake section includes an inlet space below the intake section float receiving plate, an outlet space above the intake section float receiving plate, and the inlet space. A passage space connecting the outlet space, the inlet portion inlet is provided on a lower surface of the inlet space, the inlet portion outlet is provided on a lower surface of the passage space, and the exhaust portion is the exhaust portion float. An inlet space on the lower side of the receiving plate, an outlet space on the upper side of the exhaust portion float receiving plate, and a passage space connecting the inlet space and the outlet space, the exhaust portion inlet being a lower surface of the inlet space The exhaust part outlet may be provided on the lower surface of the passage space.

  According to an embodiment of the present invention, in the hygroscopic respirator, the breathing valve has a cylindrical casing and a partition arranged along the diameter direction of the cylindrical portion of the casing, and the partition is used to increase the inside of the casing. The space may be formed with two semi-cylindrical spaces having a semicircular cross section, and the two semi-cylindrical spaces may constitute the intake portion and the exhaust portion.

  According to an embodiment of the present invention, in the hygroscopic respirator, a lower ring-shaped member is provided on the lower surface of the casing, a circular opening is formed inside the lower ring-shaped member, and the lower ring-shaped member A ring-shaped opening is formed on the outer side, the intake section inlet and the exhaust section outlet are formed in the ring-shaped opening, and the intake section outlet and the exhaust section inlet are formed in the circular opening. It's okay.

  According to the embodiment of the present invention, in the hygroscopic respirator, the screw formed on the inner peripheral surface of the lower ring-shaped member engages with the screw formed on the outer peripheral surface of the breathing valve connecting portion of the top plate. It may be constituted as follows.

  According to the present invention, in a breathing valve configured to be attachable to a body of a hygroscopic respiratory device, the breathing valve has an intake portion and an exhaust portion, and the intake portion has an intake portion inlet for inhaling air from the outside, a spherical shape An intake portion float, an intake portion float receiving plate having an intake portion breathing hole for engaging the intake portion float, and an intake portion outlet for discharging air to the main body, the intake portion The float and the intake part breathing hole constitute a check valve for introducing air from the outside into the main body, and the exhaust part is an exhaust part inlet for introducing air from the main body, An exhaust part float receiving plate provided with a spherical exhaust part float, an exhaust part breathing hole for engaging the exhaust part float, and an exhaust part outlet for exhausting air to the outside, the exhaust part The main body by the float and the exhaust breathing hole Constitute a check valve for delivering et air to the outside.

  According to an embodiment of the present invention, in the breathing valve, the intake portion includes an inlet space below the intake portion float receiving plate, an outlet space above the intake portion float receiving plate, the inlet space, and the A passage space connecting the outlet space, the inlet inlet is provided on the lower surface of the inlet space, the inlet outlet is provided on the lower surface of the passage space, and the exhaust portion is the exhaust portion float receiver. An inlet space on the lower side of the plate, an outlet space on the upper side of the exhaust part float receiving plate, and a passage space connecting the inlet space and the outlet space, and the exhaust part inlet is formed on a lower surface of the inlet space. The exhaust part outlet may be provided on a lower surface of the passage space.

  According to an embodiment of the present invention, the breathing valve has a cylindrical casing and a partition disposed along the diameter direction of the cylindrical portion of the casing, and the internal space of the casing is semicircular in cross section by the partition. Two semi-cylindrical spaces may be formed, and the two semi-cylindrical spaces may constitute the intake portion and the exhaust portion.

  According to an embodiment of the present invention, in the breathing valve, a lower ring-shaped member is provided on the lower surface of the casing, a circular opening is formed inside the lower ring-shaped member, and an outer side of the lower ring-shaped member. A ring-shaped opening is formed, the intake portion inlet and the exhaust portion outlet are formed in the ring-shaped opening, and the intake portion outlet and the exhaust portion inlet are formed in the circular opening. Good.

  According to the embodiment of the present invention, in the breathing valve, the screw formed on the inner peripheral surface of the lower ring-shaped member is engaged with the screw formed on the outer peripheral surface of the breathing valve connecting portion of the top plate. May be configured.

  The oil-filled electrical device according to the present invention includes the hygroscopic respirator.

  According to the present invention, breathing of an oil-filled electrical device can be observed even if the respiration rate is relatively small or relatively large.

FIG. 1 is a perspective view for explaining an example of the structure of a hygroscopic respirator according to the present invention. FIG. 2A is an explanatory diagram for explaining a state in which the hygroscopic respirator according to the present invention is inhaling. FIG. 2B is an explanatory diagram for explaining a state in which the hygroscopic respirator according to the present invention performs an exhaust action. FIG. 3A is a diagram showing a top surface configuration of a breathing valve of a hygroscopic respiratory apparatus according to the present invention. FIG. 3B is an explanatory diagram for explaining the configuration of the hygroscopic respirator according to the present invention, and is a diagram showing a cross-sectional configuration viewed from the direction of line AA in FIG. 3A. FIG. 3C is an explanatory diagram for explaining the configuration of the inhalation part of the breathing valve of the hygroscopic respirator according to the present invention, and is a diagram showing a cross-sectional configuration seen from the direction of line BB in FIG. 3A. FIG. 3D is an explanatory diagram for explaining the configuration of the exhaust part of the breathing valve of the hygroscopic respirator according to the present invention, and is a diagram showing a cross-sectional configuration viewed from the direction of line CC in FIG. FIG. 3E is an explanatory view illustrating an inlet and an outlet provided in the lower horizontal partition plate of the breathing valve of the hygroscopic respirator according to the present invention, and is a diagram illustrating a cross-sectional configuration viewed from the direction of line DD in FIG. 3B. It is. FIG. 4A is an explanatory diagram for explaining the operation of the inhalation portion of the breathing valve of the hygroscopic respirator according to the present invention. FIG. 4B is an explanatory diagram for explaining the operation of the exhaust part of the breathing valve of the hygroscopic respirator according to the present invention. FIG. 5 is a view showing the configuration of the outer surface of the float of the breathing valve of the hygroscopic respirator according to the present invention.

  Hereinafter, embodiments of a hygroscopic respiratory apparatus according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted.

  An example of a hygroscopic respirator according to an embodiment of the present invention will be described with reference to FIG. The hygroscopic respirator of this example has a main body 20 and a respiration valve 10 mounted thereon. The main body 20 of the hygroscopic respirator includes an upper top plate 21, a lower bottom body 22, and a glass cylinder 23 sandwiched between the two. The top plate 21 and the bottom body 22 are tightened. It is fixed by bolts 24.

  On the top plate 21, two flange seats, that is, a breathing valve connection portion 26 and a breathing pipe connection portion 28 are provided. A screw 27 is formed on the outer periphery of the breathing valve connection portion 26. A breathing pipe 36 from an oil storage device (conservator) is connected to the breathing pipe connection unit 28.

  A vent pipe 30 is provided in the glass cylinder 23. A strainer 32 having a large number of small holes is provided at the lower end of the vent pipe 30. A granular hygroscopic agent 38, for example, silica gel is loaded in the glass cylinder 23. The upper end of the vent pipe 30 is connected to the breathing pipe 36 via the breathing pipe connecting portion 28 provided on the top plate.

  The breathing valve 10 includes a cylindrical casing 100 having an upper lid 101 and a cylindrical portion 102. A lower ring-shaped member 115 is provided on the lower surface of the casing 100. A circular opening 103 is formed inside the lower ring-shaped member 115, and a ring-shaped opening 105 is formed outside. A screw 104 is formed on the inner peripheral surface of the lower ring-shaped member 115. The screw 104 is configured to engage with the screw 27 of the breathing valve connection portion 26 of the top plate 21.

  The breathing valve 10 is connected to the main body 20 by engaging the screw 104 of the lower ring-shaped member 115 of the breathing valve 10 with the screw 27 of the breathing valve connecting portion 26 of the top plate 21 of the main body 20. The circular opening 103 on the lower surface of the breathing valve 10 is connected to the inside of the glass cylinder 23 of the main body 20. A ring-shaped opening 105 on the lower surface of the breathing valve 10 is connected to the outside air. A ring filter may be provided in the ring opening 105.

  The function of the respiratory valve will be described with reference to FIGS. 2A and 2B. Details of the structure of the respiratory valve will be described later. Here, only the main part necessary for explaining the function of the intake valve will be explained.

  The breathing valve 10 has an intake part 200 and an exhaust part 300. The intake part 200 and the exhaust part 300 do not operate simultaneously. When the oil-filled electrical device is in the intake state, only the intake portion 200 operates and the exhaust portion 300 is in the closed state. When the oil-filled electrical device is in an exhaust state, only the exhaust unit 300 operates and the intake unit 200 is in a closed state.

  When the oil-filled electrical device is not breathing, the breathing valve is closed and the intake unit 200 and the exhaust unit 300 are stopped. When the oil-filled electrical device is not breathing, outside moisture (water vapor) does not enter the moisture absorbent 38 in the glass cylinder 23 of the main body.

  With reference to FIG. 2A, the inspiratory action of the hygroscopic respirator will be described. The intake section 200 is provided with a float receiving plate 201 and a float 203. A breathing hole 202 is formed in the float receiving plate 201. The breathing hole 202 is a circular hole having a tapered inner peripheral surface, and the diameter of the lower circular port is smaller than the diameter of the upper circular port. On the other hand, the float 203 is spherical. A check valve is constituted by the breathing hole 202 and the float 203. When the float 203 is engaged with the breathing hole 202, the breathing hole 202 is closed. When the float 203 floats from the breathing hole 202, the breathing hole 202 is opened.

  In the intake state, the pressure in the oil-filled electrical device is in a reduced pressure state that is lower than the atmospheric pressure. The pressure in the glass cylinder 23 of the main body of the hygroscopic respirator is smaller than atmospheric pressure. Therefore, a pressure difference is generated between the inside of the glass cylinder 23 and the outside, and the float 203 in the intake section 200 is lifted from the breathing hole 202.

  Air from the outside is sucked into the intake portion 200 via the intake portion inlet 213 on the lower surface of the intake portion 200. This air travels to the upper side of the float receiving plate 201 via the breathing hole 202, reverses, passes through the intake portion outlet 212 on the lower surface of the intake portion 200, and is sucked into the glass cylinder 23 of the main body. This air passes through the hygroscopic agent 38 in the glass cylinder 23. At this time, moisture contained in the air is absorbed by the hygroscopic agent 38. The dried air is guided to the vent pipe 30 through the strainer 32 and further sucked into the oil storage unit through the breathing pipe 36.

  Note that when air from the outside is sucked into the intake portion 200, dust carried together with the air is removed by the filter 106 provided in the ring-shaped opening 105.

  With reference to FIG. 2B, the exhaust action of the hygroscopic respirator will be described. The exhaust unit 300 is provided with a float receiving plate 301 and a float 303. A breathing hole 302 is formed in the float receiving plate 301. The breathing hole 302 is a circular hole having a tapered inner peripheral surface, and the diameter of the lower circular port is smaller than the diameter of the upper circular port. On the other hand, the float 303 is spherical. A check valve is constituted by the breathing hole 302 and the float 303. When the float 303 is engaged with the breathing hole 302, the breathing hole 302 is closed. When the float 303 is lifted from the breathing hole 302, the breathing hole 302 is opened.

  In the exhaust state, the pressure in the oil-filled electrical device is in a pressurized state greater than atmospheric pressure. The pressure in the glass cylinder 23 of the main body of the hygroscopic respirator is greater than atmospheric pressure. Therefore, a pressure difference is generated between the inside of the glass cylinder 23 and the outside, and the float 303 in the exhaust part 300 is lifted from the breathing hole 302.

  Air from the oil storage device is guided to the ventilation pipe 30 via the breathing pipe 36 and is guided into the glass cylinder 23 via the strainer 32. The air passes through the hygroscopic agent 38 in the glass cylinder 23 and is pushed into the exhaust unit 300 via the exhaust unit inlet 312 on the lower surface of the exhaust unit 300. This air travels to the upper side of the float receiving plate 301 via the breathing hole 302, reverses, passes through the exhaust part outlet 313 on the lower surface of the exhaust part 300, and is discharged to the outside.

  The structure of the breathing valve will be described with reference to FIGS. 3A to 3E. FIG. 3A shows the top configuration of the breathing valve. As described above, the breathing valve has a cylindrical casing. A partition 108 is arranged along the diameter direction of the cylindrical portion 102 of the casing. The partition 108 divides the internal space of the casing into an intake portion 200 and an exhaust portion 300. Therefore, the intake part 200 and the exhaust part 300 are each formed by a semicylindrical space having a semicircular cross section.

  The intake portion 200 is provided with a quadrant float receiving plate 201. As described above, the float receiving plate 201 is provided with a breathing hole, and a spherical float 203 is disposed therein. A float stopper 204 extends from the edge of the float receiving plate 201.

  The exhaust unit 300 is provided with a quadrant float receiving plate 301. As described above, the float receiving plate 301 is provided with a breathing hole, and a spherical float 303 is disposed there. A float stopper 304 extends from the edge of the float receiving plate 301.

  The float stoppers 204 and 304 function to prevent the floats 203 and 303 from dropping from the float receiving plates 201 and 301. For example, the outer diameter of the floats 203 and 303 is d. When the dimension of the gap between the float stoppers 204 and 304 and the partition 108 is s1, s1 <d. When the dimension of the gap between the float stoppers 204 and 304 and the cylindrical portion 102 is s2, s2 <d.

  The upper surfaces of the float stoppers 204 and 304 are inclined. Therefore, the floats 203 and 303 are always configured to return to the breathing holes of the float receiving plates 201 and 301.

  FIG. 3B shows a cross-sectional configuration of the respiratory valve as viewed from the direction of line AA in FIG. 3A. The intake section 200 is provided with a float receiving plate 201 and a lower horizontal partition plate 211 therebelow. The float receiving plate 201 is provided with a breathing hole 202, and a spherical float 203 is disposed therein. The float 203 floats when in the intake state. In the exhaust state, the float 203 is pressed against the breathing hole 202 with the pressure of the exhaust, and closes (returns) the breathing hole 202.

  The exhaust unit 300 is provided with a float receiving plate 301 and a lower horizontal partition plate 311 therebelow. The float receiving plate 301 is provided with a breathing hole 302 in which a spherical float 303 is arranged. When in the exhaust state, the float 303 is lifted. In the inhalation state, the float 303 is pressed against the breathing hole 302 by the pressure of the inspiration and closes (returns) the breathing hole 302.

  The float receiving plate 201 of the intake unit 200 and the float receiving plate 301 of the exhaust unit 300 are divided by the partition 108, but are configured to form a single float receiving plate. The lower horizontal partition plate 211 of the intake unit 200 and the lower horizontal partition plate 311 of the exhaust unit 300 are divided by the partition 108, but are configured to form a single lower horizontal partition plate.

  A lower ring-shaped member 115 is provided below the lower horizontal partition plates 211 and 311, and screws 104 are formed on the inner peripheral surface thereof. A circular opening 103 is formed inside the lower ring-shaped member 115, and a ring-shaped opening 105 is formed outside. The ring-shaped opening 105 may be provided with a ring-shaped filter.

  FIG. 3C shows a cross-sectional configuration of the breathing valve inhaler 200 as seen from the direction of line BB in FIG. 3A. The intake section 200 is provided with a float receiving plate 201 and a lower horizontal partition plate 211 therebelow. A float stopper 204 extends from the edge of the float receiving plate 201. The upper surface of the float stopper 204 is inclined. The lower horizontal partition plate 211 is provided with an intake portion outlet 212 and an intake portion inlet 213.

  Air from the outside is sucked into the inlet space 214 via the intake portion inlet 213 on the lower surface of the intake portion 200. This air travels through the breathing hole 202 to the outlet space 205 on the upper side of the float receiving plate 201, reverses in the passage space 206, passes through the intake portion outlet 212, and is sucked into the glass cylinder of the main body. .

  Note that when air from the outside is sucked into the intake section 200, dust carried along with the air is removed by the filter provided in the ring-shaped opening 105.

  FIG. 3D shows a cross-sectional configuration of the exhaust part 300 of the breathing valve as seen from the direction of line CC in FIG. 3A. The exhaust unit 300 is provided with a float receiving plate 301 and a lower horizontal partition plate 311 therebelow. A float stopper 304 extends from the edge of the float receiving plate 301. The upper surface of the float stopper 304 is inclined. The lower horizontal partition plate 311 is provided with an exhaust part inlet 312 and an exhaust part outlet 313.

  Air from the inside of the glass cylinder of the main body is pushed into the inlet space 314 via the exhaust part inlet 312 on the lower surface of the exhaust part 300. This air travels through the breathing hole 302 to the outlet space 305 on the upper side of the float receiving plate 301, reverses in the passage space 306, passes through the exhaust part outlet 313, and is discharged to the outside.

  FIG. 3E shows a cross-sectional configuration of the lower horizontal partition plate of the respiratory valve as viewed from the direction of line DD in FIG. 3B. The lower horizontal partition plate includes a lower horizontal partition plate 211 of the intake unit 200 and a lower horizontal partition plate 311 of the exhaust unit 300. The lower horizontal partition plate 211 of the intake unit 200 is formed with an intake unit outlet 212 and an intake unit inlet 213. The lower horizontal partition plate 311 of the exhaust part 300 is formed with an exhaust part inlet 312 and an exhaust part outlet 313. The intake section outlet 212 and the exhaust section inlet 312 are quadrant holes, and the intake section inlet 213 and the exhaust section outlet 313 are quadrant holes.

  With reference to FIG. 4A, operation | movement of the inhalation part 200 of the respiration valve 10 which concerns on this embodiment is demonstrated. Air from the outside is sucked into the inlet space 214 via the intake portion inlet 213 on the lower surface of the intake portion 200. This air travels through the breathing hole 202 to the outlet space 205 on the upper side of the float receiving plate 201. The exit space 205 and the passage space 206 are connected. Therefore, the air guided to the outlet space 205 passes through the intake space outlet 212 via the passage space 206 and is sucked into the glass cylinder of the main body.

  With reference to FIG. 4B, operation | movement of the exhaust part 300 of the breathing valve 10 which concerns on this embodiment is demonstrated. Air from the inside of the glass cylinder of the main body is pushed into the inlet space 314 via the exhaust part inlet 312 on the lower surface of the exhaust part 300. This air proceeds to the outlet space 305 on the upper side of the float receiving plate 301 via the breathing hole 302. The outlet space 305 and the passage space 306 are connected. Therefore, the air guided to the outlet space 305 passes through the exhaust space outlet 313 via the passage space 306 and is discharged to the outside.

  According to the embodiment of the present invention, the breathing state of the oil-filled electrical device can be known by observing the float 203 of the intake section 200. For example, when the float 203 is floating, it can be determined that the oil-filled electrical device is in the intake state. That is, it can be determined that the oil-filled electrical device and the respirator normally inhale and are not malfunctioning. Further, by measuring the floating amount of the float 203, it is possible to know the approximate amount of intake air.

  Similarly, by observing the float 303 of the exhaust unit 300, the breathing state of the oil-filled electrical device can be known. For example, when the float 303 is floating, it can be determined that the oil-filled electrical device is in an exhaust state. That is, it can be determined that the oil-filled electrical device and the respirator are normally exhausted and not broken. Further, by measuring the floating amount of the float 303, it is possible to know the approximate amount of the exhaust amount.

  According to the embodiment of the present invention, breathing of the oil-filled electrical device can be observed even if the respiration rate is relatively small or relatively large.

  However, when the float 203 of the intake section 200 is stationary on the breathing hole 202, the oil-filled electrical device is in the exhaust state and not in the intake state, the intake amount is relatively small, or the oil-in It is unknown whether the electrical equipment or the respiratory system is not normally inhaling due to a failure. When the float 303 of the exhaust unit 300 is stationary on the breathing hole 302, the oil-filled electrical device is in the intake state and not in the exhaust state, the displacement is relatively small, or the oil-filled electrical device Or it is unknown whether the respiratory system is not exhausting normally due to a failure.

  Therefore, in this embodiment, a function is provided for detecting whether the oil-filled electrical device is not breathing or whether the oil-filled electrical device or the respirator is not breathing normally due to a failure.

  An example of the pattern on the outer surface of the floats 203 and 303 will be described with reference to FIG. In the present embodiment, various patterns, numbers, symbols, or combinations thereof are described on the outer surfaces of the floats 203 and 303. For example, in FIG. 5C, the letter A represents the front, the letters B and D are the side faces, the letter E is the top face, the letter F is the bottom face, and the letter C is the back face. In FIG. 5D, numeral 1 represents the front surface, numerals 2 and 4 represent the side surfaces, numeral 5 represents the top surface, numeral 6 represents the bottom surface, and numeral 3 represents the back surface. It is assumed that the floats 203 and 303 are lifted from a state where they are resting on the breathing holes 202 and 302 and then returned to the breathing holes 202 and 302 again and resting there. The floats 203 and 303 change their rotational positions before and after floating.

  Accordingly, the positions of the patterns on the outer surfaces of the floats 203 and 303 are observed or photographed and recorded at predetermined intervals. The observation or imaging cycle may be set to an arbitrary value based on the respiratory cycle. The pattern or the like of the outer surface of the float 203 or 303 that was observed or photographed last time is compared with the pattern or the like of the outer surface of the float 203 or 303 that was observed or photographed this time. , 303 has risen, that is, it can be determined that breathing has been performed.

  On the other hand, the pattern or the like of the outer surface of the float 203 or 303 that was observed or photographed last time is compared with the pattern or the like of the outer surface of the float 203 or 303 that is observed or photographed this time. 303 is stationary on the breathing holes 202 and 302. In this case, it is possible to determine that the oil-filled electrical device or the respirator is not normally breathing due to a failure in consideration of the operation status of the oil-filled electrical device. Moreover, what is necessary is just to investigate the cause.

  Although the hygroscopic respirator according to the present embodiment has been described above, these are examples and do not limit the scope of the present invention. Additions, deletions, changes, improvements, and the like that can be easily made by those skilled in the art with respect to the present embodiment are within the scope of the present invention. The technical scope of the present invention is defined by the appended claims.

  DESCRIPTION OF SYMBOLS 10 ... Breathing valve, 20 ... Main body, 21 ... Top plate, 22 ... Bottom body, 23 ... Glass cylinder, 24 ... Clamping bolt, 26 ... Breathing valve connection part, 27 ... Screw, 28 ... Breathing pipe connection part, 30 ... 32 ... Strainer 36 ... Breathing pipe 38 ... Hygroscopic agent 100 ... Casing 101 ... Upper lid 102 ... Cylindrical part 103 ... Circular opening 104 ... Screw 105 ... Ring-shaped opening 106 ... Ring Filter 108, Partition 115, Lower ring member 200, Inlet part 201, Float plate, 202 Breathing hole 203, Float 204, Float stopper, 205 Exit space, 206 Passage space 210 ... Lower vertical partition plate, 211 ... Lower horizontal partition plate, 212 ... Suction part outlet, 213 ... Suction part inlet, 214 ... Inlet empty , 300 ... exhaust part, 301 ... float receiving plate, 302 ... breathing hole, 303 ... float, 304 ... float stopper, 305 ... outlet space, 306 ... passage space, 310 ... lower vertical partition plate, 311 ... lower horizontal partition plate, 312 ... Exhaust section inlet, 313 ... Exhaust section outlet, 314 ... Entrance space

Claims (11)

In a hygroscopic respirator having a breathing valve having an intake part and an exhaust part, and a main body to which the breathing valve can be attached,
The main body includes a top plate, a bottom body, a glass cylinder sandwiched between the top plate and the bottom body, a vent pipe provided in the glass cylinder, and a moisture absorbent filled in the glass cylinder. And the top plate is provided with a breathing valve connecting portion for connecting the breathing valve, and a breathing pipe connecting portion for connecting the vent pipe to a breathing pipe from an oil storage device. And
The intake section includes an intake section inlet for inhaling air from the outside, a spherical intake section float, and an intake section float receiving plate having an intake section breathing hole for engaging the intake section float; An intake portion outlet for discharging air to the main body, and a check valve for introducing air from the outside into the main body by the intake portion float and the intake portion breathing hole,
The exhaust part includes an exhaust part inlet for introducing air from the main body, a spherical exhaust part float, and an exhaust part float receiving plate provided with an exhaust part breathing hole for engaging the exhaust part float. An exhaust part outlet for exhausting air to the outside, and a check valve for sending air from the main body to the outside is constituted by the exhaust part float and the exhaust breathing hole. Features a hygroscopic breathing apparatus. The hygroscopic respirator according to claim 1, wherein
The intake portion has an inlet space below the intake portion float receiving plate, an outlet space above the intake portion float receiving plate, and a passage space connecting the inlet space and the outlet space, The intake portion inlet is provided on the lower surface of the inlet space, the intake portion outlet is provided on the lower surface of the passage space,
The exhaust part has an inlet space below the exhaust part float receiving plate, an outlet space above the exhaust part float receiving plate, and a passage space connecting the inlet space and the outlet space, The moisture-absorbing respirator according to claim 1, wherein the exhaust part inlet is provided on a lower surface of the inlet space, and the exhaust part outlet is provided on a lower surface of the passage space. The hygroscopic respirator according to claim 1 or 2,
The breathing valve has a cylindrical casing and a partition arranged along a diameter direction of the cylindrical portion of the casing, and the internal space of the casing by the partition has two semicylindrical spaces having a semicircular cross section. And the two semi-cylindrical spaces constitute the intake part and the exhaust part. The hygroscopic respirator according to claim 3,
A lower ring-shaped member is provided on the lower surface of the casing, a circular opening is formed inside the lower ring-shaped member, and a ring-shaped opening is formed outside the lower ring-shaped member,
The inhalation breathing apparatus, wherein the intake section inlet and the exhaust section outlet are formed in the ring-shaped opening, and the intake section outlet and the exhaust section inlet are formed in the circular opening. The hygroscopic respirator according to claim 4,
A hygroscopic respirator characterized in that a screw formed on an inner peripheral surface of the lower ring-shaped member is engaged with a screw formed on an outer peripheral surface of a breathing valve connecting portion of the top plate. . In a breathing valve configured to be attachable to the body of a hygroscopic respiratory
Have an intake and exhaust,
The intake section includes an intake section inlet for inhaling air from the outside, a spherical intake section float, and an intake section float receiving plate having an intake section breathing hole for engaging the intake section float; An intake portion outlet for discharging air to the main body, and a check valve for introducing air from the outside into the main body by the intake portion float and the intake portion breathing hole,
The exhaust part includes an exhaust part inlet for introducing air from the main body, a spherical exhaust part float, and an exhaust part float receiving plate provided with an exhaust part breathing hole for engaging the exhaust part float. An exhaust part outlet for exhausting air to the outside, and a check valve for sending air from the main body to the outside is constituted by the exhaust part float and the exhaust breathing hole. Features a breathing valve. The respiratory valve according to claim 6,
The intake portion has an inlet space below the intake portion float receiving plate, an outlet space above the intake portion float receiving plate, and a passage space connecting the inlet space and the outlet space, The intake portion inlet is provided on the lower surface of the inlet space, the intake portion outlet is provided on the lower surface of the passage space,
The exhaust part has an inlet space below the exhaust part float receiving plate, an outlet space above the exhaust part float receiving plate, and a passage space connecting the inlet space and the outlet space, The breathing valve, wherein an exhaust part inlet is provided on a lower surface of the inlet space, and the exhaust part outlet is provided on a lower surface of the passage space. The respiratory valve according to claim 6 or 7,
A cylindrical casing and a partition arranged along a diameter direction of the cylindrical portion of the casing, and the partition forms two semi-cylindrical spaces having a semicircular cross section in the internal space of the casing; The breathing valve, wherein the intake part and the exhaust part are constituted by two semi-cylindrical spaces. The respiratory valve according to claim 8,
A lower ring-shaped member is provided on the lower surface of the casing, a circular opening is formed inside the lower ring-shaped member, and a ring-shaped opening is formed outside the lower ring-shaped member,
The breathing valve according to claim 1, wherein the intake section outlet and the exhaust section outlet are formed in the ring-shaped opening, and the intake section outlet and the exhaust section inlet are formed in the circular opening. The respiratory valve according to claim 9,
A breathing valve, wherein a screw formed on an inner peripheral surface of the lower ring-shaped member is configured to engage with a screw formed on an outer peripheral surface of a breathing valve connecting portion of the top plate.   An oil-filled electrical device comprising the hygroscopic respirator according to any one of claims 1 to 5.

Images