JP3402789B2 - Thermal steam trap - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat-sensitive steam trap which traps steam flowing out of a heat exchanger of equipment using steam such as a steam heater so as not to leak, and discharges only condensed water. Is.

[0002]

2. Description of the Related Art A heat-sensitive steam trap of this type has a high-temperature, high-pressure primary-side fluid containing steam that flows into the trap chamber from an inlet port. At, the thermal expansion medium enclosed by the flexible diaphragm receives heat from the primary fluid and expands, displacing the diaphragm. The valve element attached to this diaphragm sits on the valve seat and closes the passage between the trap chamber and the outlet, preventing vapor from leaking out. On the other hand, if the temperature of the fluid drops below a predetermined value due to heat dissipation or if low-temperature condensate flows in from the inlet, the thermal expansion medium contracts and the pressure of the primary fluid presses the diaphragm. The valve body separates from the valve seat, and only condensate is discharged from the outlet.

By the way, in the heat-sensitive steam trap as described above, since the thin flexible diaphragm is repeatedly deformed, the diaphragm may be broken. When the diaphragm breaks, the thermal expansion medium inside the diaphragm flows out from the damaged part of the diaphragm, the pressure difference between the space in which the thermal expansion medium is enclosed and the primary side fluid outside the space disappears, and the valve body and valve seat The valve element is attracted to the valve seat by the negative pressure generated by the fluid passing through the narrow space between the valve and the valve, and the valve is closed.

If the valve remains closed, the condensed water cannot be discharged, so that the condensed water is accumulated in the heat exchanger on the upstream side to lower the heat exchange efficiency, or the condensed water has a high temperature steam. The water and hammer will be generated due to the rapid contraction caused by touching, and the heat exchanger and piping will be damaged. Therefore, various heat-actuated steam traps have been proposed to solve these problems (Japanese Patent Laid-Open No. 4-2).
62196, JP-A-4-370497, JP-A-5-
(See each publication of No. 240399).

However, in any of the steam traps described above, when the diaphragm is damaged, the valve is opened and the valve is kept open.
The valve opening state has insufficient reliability and lacks reliability, and has a drawback that the configuration is complicated.

Therefore, the present invention provides a heat-sensitive steam trap which has a simplified and highly reliable structure, and can reliably open the valve even if the heat-sensitive element is damaged and can maintain the valve-opened state. The purpose is to

[0007]

In order to achieve the above object, a heat-sensitive steam trap according to a first aspect of the present invention is characterized in that a casing is provided with an inlet for a primary fluid containing steam and a condensate. is outlet and trap chamber of the secondary fluid containing formation, the trap chamber, is heat sensitive element is disposed having a thermal expansion medium to heat from the primary side fluid, the thermosensitive element, in the case, closed intermediate portions have a inward space communicating with the outlet and a bellows <br/>'s shape projecting outwardly at the valve position and the outer peripheral edge cable to the outside of the bellows
And a diaphragm which is fixed to the scan, and the bellows
Enclosed space that encloses the thermal expansion medium with the diaphragm
A space is formed between the diaphragm and the trap chamber.
A valve body that opens and closes between the outlets is attached, and the bellows has a pressure receiving surface that receives a pressure that contracts when the valve is opened based on a pressure difference between the enclosed space and the inner space.

Further, in the heat-sensitive steam trap of the second invention according to claim 2, the inlet of the primary fluid containing steam, the outlet of the secondary fluid containing condensate, and the trap chamber are provided in the casing. A heat-sensitive element, which is formed and has a thermal expansion medium that receives heat from the primary side fluid enclosed between a cylindrical inner bellows and a cylindrical outer bellows, is arranged. At one end, a secondary passage communicating with the outlet is formed, one end of the thermosensitive element is supported by the casing, and the other end is provided between the trap chamber and the secondary passage. A valve body to be opened and closed is attached, and a pressure receiving portion having an inner diameter smaller than an effective diameter of the inner bellows and receiving the pressure of the primary side fluid in a valve opening direction is formed on an outer peripheral portion of the valve body. .

[0009]

Furthermore, in the heat-sensitive steam trap of the third invention according to claim 3 , the casing contains steam.
An inlet for the secondary fluid, an outlet for the secondary fluid containing condensate, and a trap chamber are formed, and further, between the case, the thermal expansion medium that receives heat from the primary fluid , and the case.
A heat- sensitive element having a diaphragm forming a sealed space for sealing the thermal expansion medium, a valve body attached to the diaphragm to open and close between the trap chamber and the outlet, and a valve body opened to the valve body. And a spring member that applies a spring force in the valve direction, and the valve body is formed with an internal passage that is in constant communication with the trap chamber and that is opened and closed by the opening / closing operation of the valve body. .

[0011]

In the heat-sensitive steam trap of the first aspect of the invention, when the primary fluid flowing from the inlet is high temperature steam obtained from water or high temperature condensate close to the saturated steam temperature, the thermal expansion medium Receives heat from the primary side fluid and expands, the pressure in the enclosed space of this thermal expansion medium increases and deforms the diaphragm and bellows, displacing the valve element attached to the heat sensitive element and moving it from the trap chamber to the outlet. The valve body closes the passage that connects to it, preventing hot steam from leaking from the outlet. On the other hand, when the temperature of the primary side fluid in the trap chamber drops due to heat dissipation and becomes lower than a predetermined value, or when low-temperature condensate flows in from the inlet, the thermal expansion medium contracts and the pressure in the enclosed space increases. Since the pressure drops, the valve body is pressed by the high pressure of the primary side fluid to be opened.

When the valve is closed, the diaphragm
The part communicating with the inner space or the bellows is damaged.
The thermal expansion medium from the enclosed space to the outlet,
The pressure leaks into the inner space and the pressure in the enclosed space decreases.Runo
Therefore, the valve closing force acting on the valve body from the heat sensitive element disappears.
It Therefore, the valve body receives the high pressure of the primary side fluid.
The valve is opened. After that, the thermal expansion medium of the heat-sensitive element leaked.
Therefore, the volume of heat received from the primary fluid
The valve closing force can be applied to the valve body without any change.
I can't come. Therefore, the valve body opens when it receives the pressure of the primary side fluid.
Hold the valve state. Also, when the valve is open, the bellows
If damaged, the valve open state is maintained.

On the other hand, when the portion of the diaphragm facing the trap chamber is broken in the valve closed state, the thermal expansion medium in the enclosed space leaks into the trap chamber and the pressure in the enclosed space becomes the pressure of the primary side fluid. The pressure difference between the enclosed space and the inner space acts on the pressure receiving surface of the bellows to displace the valve element to the open state. After that, the thermal element
Since the thermal expansion medium is leaking, the valve closing force cannot be applied to the valve body. Therefore, the valve body maintains the valve open state. When the diaphragm is damaged in the valve open state, the valve open state is maintained as it is.

In the heat-sensitive steam trap of the second invention, the thermal expansion medium enclosed between the inner bellows and the outer bellows expands or contracts according to the temperature of the primary side fluid to displace the valve body and close it. Get valve or open state. When the inner bellows is broken in the valve closed state, the thermal expansion medium leaks from the enclosed space to the secondary passage, and the pressure in the enclosed space is
Since the pressure of the secondary fluid in the secondary passage is reduced, the valve closing force acting on the valve body due to the expansion of the thermal expansion medium disappears. Therefore, the valve body is opened by the high pressure of the primary fluid in the pressure receiving portion. After that, the heat-sensitive element cannot apply the valve closing force to the valve body because the thermal expansion medium leaks, and the valve body keeps the valve open state. If the inner bellows is damaged in the valve open state, the valve open state is maintained.

When the outer bellows is broken in the closed state, the thermal expansion medium in the enclosed space leaks into the trap chamber, and the pressure in the enclosed space becomes the same as the pressure of the primary side fluid in the trap chamber. On the other hand, the pressure in the secondary passage is maintained at a low pressure of the secondary fluid by the inner bellows and the valve body. Here, since the inner diameter of the pressure receiving portion is smaller than the effective diameter of the inner bellows, the portion of the pressure receiving portion located on the inner diameter side of the inner diameter of the inner bellows is the difference between the pressures of the primary fluid and the secondary fluid. The pressure is received in the valve opening direction, and the valve body is displaced to the valve open state. Therefore, the valve body opens due to the pressure of the primary fluid acting on the pressure receiving portion. After that, the heat-sensitive element cannot apply the valve closing force to the valve body because the thermal expansion medium leaks, and the valve body keeps the valve open state. If the outer bellows is damaged in the valve open state, the valve open state is maintained.

The valve opening / closing operation due to the temperature change of the primary fluid is performed by contraction and expansion of the thermal expansion medium that receives heat from the primary fluid, as in the first aspect of the invention.

In the second aspect of the invention, the heat-sensitive element has a simple structure in which two types of bellows, which are both cylindrical and have different diameters, are concentrically arranged and a thermal expansion medium is enclosed between the bellows. . Moreover, one end of this heat-sensitive element is supported by the casing, the other end is provided with a valve element, and the fluid is a simplified flow path to the outlet through the secondary passage provided in the inner space of the inner bellows. Since it is flushed to the outside, the overall configuration is simple and highly reliable.

[0018]

[0019]

In the third aspect of the invention, when the heat-sensitive element is broken in the valve closed state, the pressure in the enclosed space of the thermal expansion medium decreases to the pressure of the primary side fluid in the trap chamber due to the leakage of the thermal expansion medium. . At this time, the pressure in the internal space of the valve body, which is in constant communication with the trap chamber, is kept the same as the pressure of the primary side fluid because it is blocked from the outlet due to the valve closed state. That is, when the heat-sensitive element is damaged, the pressure in the heat-sensitive element that acts in the valve closing direction is canceled by the pressure in the internal space, so that only a small valve closing force due to the fluid pressure acts on the valve body. As a result, the valve body can be surely opened by the slight spring force of the spring member, and the opened state can be maintained. When the thermosensitive element is damaged in the valve open state, the valve open state is maintained as it is due to the spring force of the spring member.

According to the third aspect of the invention, the valve element is surely opened by the spring force of the spring member added thereto,
Further, since the spring force of the spring member is directly applied to the valve body, the effect of a simple structure can be obtained. Further, as described above, since the spring force of the spring member can be small, the expansion force of the thermal expansion medium of the heat-sensitive element that overcomes this spring force and generates the valve closing force can also be small. The pressure difference between the enclosed space and the trap chamber does not increase. Therefore, member interposed to undergo expansion and contraction of the thermal expansion medium deformation between the trap chamber and the sealed space in the heat-sensitive element, for example Da Iyafuramu the durability is improved burden becomes lighter.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described in detail below with reference to the drawings. [First Invention] FIG. 1 is a vertical sectional view showing a valve open state of a heat-sensitive steam trap of the first invention, FIG. 2 (a) is a vertical sectional view showing a valve closed state of the steam trap, and FIG. Is (a)
FIG.

In FIG. 1, a casing 1 which constitutes an exterior body includes a lower casing member 2 and an upper casing member 3.
Are fitted to each other with the seal material 4 interposed therebetween and are fixed by bolts (not shown). Upper casing member 3
A trap chamber 5 is provided inside, and a lower casing member 2 is provided with an inlet 6 for a high-temperature, high-pressure primary fluid containing steam flowing out from a heat exchanger and a low-temperature, low-pressure containing condensate. Secondary fluid outlet ports 7 are formed respectively. Female threads for connection are formed on the inner peripheral surfaces of the inlet 6 and the outlet 7.

The lower casing member 2 has the inlet 6
An inlet passage 9 that communicates with the trap chamber 5 and an outlet passage 10 that communicates the trap chamber 5 with the outlet 7 are formed by partition walls 8. Further, in the lower casing member 2, a support portion 12 in which an inflow side portion of the outlet passage 10 projects toward the trap chamber 5 side, and a central portion of the tip of the support portion 12 protrudes around the inlet of the outlet passage 10. And a valve seat 19 formed on the support member 12, and a heat sensitive element 26 is attached to the support portion 12.

The thermosensitive element 26 has an exterior body formed by a substantially bag-shaped case 24 having a lower opening. The case 24 includes a first case body 22 having an inverted dish shape and a second case body 23 having a mounting tube portion 13 formed in a central portion thereof. It is fixed. The case 24 includes the mounting tube portion 13 and the support portion 1
It is fitted into the outer peripheral surface of 2 from above, and is pressed and fixed to the support portion 12 by the upper casing member 3. Second
The case body 23 has a plurality of through holes 3 communicating with the trap chamber 5.
8 is formed.

Inside the case 24, an upper first diaphragm (upper half of diaphragm) 30 and a lower second diaphragm (lower half of diaphragm) 31 each having an opening in the central portion overlap their outer peripheral ends with each other. It is sandwiched and fixed between both case bodies 22 and 23 in the combined facing state. A ring-shaped valve element 33 corresponding to the valve seat 19 is fixed to the opening edge portion at the center of the second diaphragm 31 by welding.

A bellows 16 having a deformed cylindrical shape with a vertically intermediate portion projecting outward is arranged between the diaphragms 30 and 31 with the inner space 17 thereof facing the communication hole 18 of the ring-shaped valve body 33. And the upper opening edge of the first diaphragm 30 and the lower opening edge of the valve element 33.
Are welded and fixed to each other. As shown in FIG. 2 (b), the bellows 16 has two cylindrical bellows parts 16a and 16b whose diameters sequentially increase along the axial direction, and the large-diameter-side opening peripheral ends of the bellows parts 16a and 16b are mutually adjacent. Butted and welded. The opening diameter on the small diameter side (lower end) of the second bellows component 16b on the lower side is smaller than the opening diameter on the small diameter side (upper end) of the first bellows component 16a on the upper side.
A portion of the bellows component 16b that extends toward the inner diameter side of the first bellows component 16a is a pressure receiving surface 20 that receives a pressure that contracts in the valve opening direction. The welded portions of both diaphragms 30 and 31 and bellows 16 are schematically illustrated by circles.

A thermal expansion medium 36 is enclosed in a heat-sensitive chamber (enclosed space) 35 which is formed by being surrounded by the bellows 16 and the diaphragms 30 and 31 located outside the bellows 16. The thermal expansion medium 36 is a fluid having a saturated vapor temperature lower than that of water and a saturated pressure higher than that of water at the same temperature, for example, alcohol. Both diaphragms 30 and 31 are made of a flexible and corrosion-resistant material having a small thickness, for example, a stainless steel plate. As the material of the case 24, for example, stainless steel having excellent corrosion resistance and thermal conductivity is used.

Next, the operation of the above embodiment will be described in detail. 1 and 2A, P1 is the pressure of the primary fluid, P2 is the pressure of the secondary fluid, and P3 is the thermosensitive element 26.
The respective pressures inside the heat sensitive chamber 35 are shown. Further, for example, when the pressure P1 of the primary side fluid is 5 kgf / cm ² · g and the saturated vapor temperature of the primary side fluid is 158 ° C., in this embodiment, for example, the temperature of the thermal expansion medium 36 is 150 ° C. The saturation characteristic of the thermal expansion medium 36 and the diaphragm are such that the valve is completely closed when the temperature rises above 130 ° C. and is completely opened when the temperature falls below 130 ° C. Curvatures of 30 and 31 are set.

When the temperature of the primary fluid in the trap chamber 5 is lower than a predetermined value (for example, 130 ° C.), the thermal expansion medium 36 which receives heat from the primary fluid contracts and its volume becomes small, so that the heat-sensitive chamber The pressure P3 in 35 becomes lower than the pressure P1 of the primary side fluid in the trap chamber 5. The pressure P1 of the primary fluid acts as a pushing-up force on the second diaphragm 31 through the through hole 38, and the valve body 33 separates from the valve seat 19 to be in the valve open state shown in FIG.

In the valve-opened state shown in FIG. 1, when a primary fluid containing high-temperature steam flows in from the inlet 6, this 1
Heat is conducted from the secondary fluid to the thermal expansion medium 36. here,
Since the saturated vapor temperature of the thermal expansion medium 36 is lower than that of the primary fluid, even if the primary fluid is condensate and is equal to or lower than the saturated vapor temperature of water, the saturated vapor temperature of the thermal expansion medium 36 is equal to or higher than the saturated vapor temperature. In some cases, the thermal expansion medium 36 is vaporized and expanded by receiving heat, and the pressure P3 in the heat-sensitive chamber 35 becomes higher than the pressure P1 of the primary fluid, so that the volume in the heat-sensitive chamber 35 increases.
Therefore, the second diaphragm 30 is displaced downward while deforming the bellows 16 so as to open in accordance with the expansion of the thermal expansion medium 36 of the heat sensitive element 26, and the second diaphragm 31 is displaced.
The valve body 33 attached to the valve seat 33 is seated on the valve seat 19, and the outlet passage 10 that connects the trap chamber 5 to the outlet 7 is closed, and the valve is closed as shown in FIG. Of steam of the above is prevented from leaking from the outlet 7.

Next, when the temperature of the fluid in the trap chamber 5 drops due to heat dissipation and becomes lower than a predetermined value (for example, 130 ° C.), or when low-temperature condensate flows in from the inlet 6, the thermal expansion medium 36. Contracts to reduce the volume in the heat-sensitive chamber 35, and the valve-closing force acting on the valve element 33 from the heat-sensitive element 26 becomes lower than the valve-opening force due to the pressure P1 of the primary fluid,
The valve element 33 receives the pressure P1 of the primary side fluid via the second diaphragm 31 and separates from the valve seat 19, and enters the valve open state shown in FIG. It flows out from the outlet 7.

When the first diaphragm 30 or the bellows 16 communicating with the inner space 17 is broken in the valve closed state shown in FIG. 2A, the thermal expansion medium 36 is connected to the outlet 7 by the low pressure. The pressure P3 in the heat sensitive chamber 35 is reduced to the pressure P2 of the secondary side fluid in the inner space 17 through the damaged portion of the first diaphragm 30 or the bellows 16. Therefore, the heat sensitive element 2
The valve closing force acting on the valve body 33 from 6 disappears, and the valve body 33 receives the high pressure P1 of the primary side fluid via the second diaphragm 31 and separates from the valve seat 19 to open the valve. Becomes

After that, since the thermal expansion medium 36 leaks, the thermosensitive element 35 does not change its volume due to the heat received from the primary side fluid, and can exert a valve closing force on the valve element 33. Disappear. Therefore, the valve element 33 receives the pressure P1 of the primary fluid and maintains the valve open state in which it is separated from the valve seat 19. When the first diaphragm 30 or the bellows 16 is damaged in the valve open state, the valve open state is maintained as it is.

On the other hand, in the valve closed state, when the second diaphragm 31 facing the trap chamber 5 is damaged, the heat sensitive chamber 3
The thermal expansion medium 36 in 5 leaks into the trap chamber 5, the pressure in the heat sensitive chamber 35 becomes equal to the pressure P1 of the primary side fluid, and the pressure difference (P1−P1) between the heat sensitive chamber 35 and the inner space 17 P
2) acts on the bellows 16. At this time, FIG. 2 (b)
As shown in FIG.
Although the pushing-down force and the pushing-up force of the same pressure (P1-P2) per unit area act on the bellows parts 16a and 16b, the pressure acting on the pressure receiving surface 20 on the inner diameter side of the second bellows part 16b. Since the pushing-up force exceeds, the valve body 33 is moved away from the valve seat 19 and displaced to the open state.

After that, since the thermal expansion medium 36 leaks, the thermosensitive element 35 cannot exert a valve closing force on the valve element 33. Therefore, the valve body 33 maintains the valve open state. In addition, in the valve open state, the second diaphragm 3
If 1 is damaged, the valve open state is maintained as it is.

If both diaphragms 30 and 31 are damaged, the primary side fluid is
Each of the damaged portions 31 flows out from the outlet 7 through the inner space 17 and the outlet passage 10. After that, the pressure of the primary-side fluid flowing into the heat-sensitive chamber 35 acts on the pressure receiving surface 20 of the bellows 16 to open the valve.
Even when the valve 3 is maintained in the valve closed state, the fluid flows out through the above-mentioned path, so that there is no inconvenience that condensate accumulates in the trap chamber 5.

[Second Invention] FIG. 3 is a vertical sectional view showing a heat-sensitive steam trap of the second invention in a valve open state, and FIG. 4 is a vertical sectional view showing the steam trap in a valve closed state. In FIG. 3, the casing 1 is composed of a lower casing member 39 and an upper casing member 40, and the entire interior surrounded by both casing members 39, 40 is a trap chamber 5.

In the heat-sensitive element 26, an inner bellows 41 and an outer bellows 42, both of which have a cylindrical shape, are concentrically arranged, and a closing plate 4 is provided on both open end faces of both bellows 41, 42.
Space 3 between both bellows 41, 42 by fixing 3, 44
5, the cylindrical space 35 is used as a heat-sensitive chamber, and the heat-expansion medium 36 is enclosed in the heat-sensitive chamber 35. The thermosensitive element 26 has a closing plate 44 on one end side thereof fixed to the upper casing body 40 and attached in a suspended state. The valve element 33 is fixed to the closing plate 43 on the other end side. The secondary passage 46 is provided radially inward of the inner bellows 41.
The secondary side passage 46 has an inflow hole 47 and a valve body 3 formed in the central portion of the closing plate 43 on the other end side.
It communicates with the trap chamber 5 through the communication hole 18 of No. 3, and also communicates with the outlet 7 through the outflow hole 45 formed in the closing plate 44 on one end side.

The lower casing member 39 includes a valve body 3
A valve seat 49 is fixedly attached so as to face 3. The pressure receiving portion 4 is arranged radially outward from the outer peripheral portion of the valve element 33 in the closing plate 43.
8 is formed. The inner diameter of the pressure receiving portion 48 is set to be smaller than the effective diameter D of the inner bellows 41, and the pressure of the primary fluid is opened in the valve opening direction at the portion on the inner diameter side of the effective diameter D, that is, in FIG. Receive upwards. The effective diameter D in this embodiment is the average diameter of the inner bellows 41.

The valve opening / closing operation according to the temperature change of the primary side fluid in the second aspect of the invention is performed by contraction and expansion of the thermal expansion medium 36 that receives heat from the primary side fluid, as in the first aspect of the invention.

Next, when the inner bellows 41 is broken in the valve closed state shown in FIG. 4, the thermal expansion medium 36 leaks from the heat-sensitive chamber 35 to the secondary passage 46, and the pressure P3 in the heat-sensitive chamber 35 becomes 2 The pressure P2 of the secondary fluid in the secondary passage 46 drops. Therefore, the valve-closing force acting on the valve element 33 due to the expansion of the thermal expansion medium 36 disappears, and
The high pressure P1 of the secondary side fluid is received via the pressure receiving portion 48 and separated from the valve seat 49 to open the valve. After that, the heat sensitive room 35
Since the thermal expansion medium 36 is leaking, the volume change due to the heat received from the primary fluid does not occur, and the valve closing force cannot be applied to the valve body 33. Therefore, the valve body 33 maintains the valve open state in which it is separated from the valve seat 49 by the pressure P1 of the primary fluid. When the inner bellows 41 is damaged in the valve open state, the valve open state is maintained as it is.

On the other hand, in the valve closed state, the outer bellows 42
When is damaged, the thermal expansion medium 36 in the heat sensitive chamber 35 leaks into the trap chamber 5, and the pressure P3 in the heat sensitive chamber 35 becomes the same as the pressure P1 of the primary side fluid in the trap chamber 5. On the other hand, the pressure in the secondary passage 46 is maintained at the low pressure P2 of the secondary fluid by the inner bellows 41 and the valve element 33. Here, since the inner diameter of the pressure receiving portion 48 is smaller than the effective diameter D of the inner bellows 41, the portion 48a located on the inner diameter side of the inner bellows 41 in this pressure receiving portion 48.
Receives the pressure difference P1-P2 between the pressure P1 of the primary fluid and the pressure of the secondary fluid in the valve opening direction (upward direction in FIG. 4), and displaces the valve element 33 to the valve open state.

After that, since the thermal expansion medium 36 is leaking from the heat sensitive element 26, the valve closing force cannot be applied to the valve body 33, so that the valve body 33 maintains the valve open state. When the outer bellows 42 is damaged in the valve open state, the valve open state is maintained as it is.

In this second invention, both casing members 3
Reference numerals 9 and 40 are mere box shapes, and the passages 9 and 10 in the first aspect of the invention and the support portion 12 having the valve seat 19 and the like are unnecessary. Furthermore, the heat-sensitive elements 26 are both tubular and have a small diameter. It has a simple structure in which two different types of bellows 41, 42 are concentrically arranged. Therefore, the entire structure is simplified and has high reliability.

[ Reference Example Not Included in the Present Invention] FIG. 5 is a vertical cross-sectional view showing a thermosensitive steam trap of a reference example not included in the present invention in an open state, and FIG. 6 shows a closed state of the steam trap. FIG. In this embodiment, a valve seat member 11 is attached to the upstream side opening of the outlet passage 10 in the lower casing member 2 by screw connection, and the trap chamber 5 and the outlet passage 1 are attached to the valve seat member 11.
An introduction hole 15 communicating with 0 and a valve seat 19 projecting in a ring shape are formed at a hole edge portion of an upper end opening of the introduction hole 15.

In the heat-sensitive element 26, a single diaphragm 31 is provided in the case 24, and the outer peripheral ends thereof are provided in both case bodies 22 and 23.
The diaphragm 31 has a simple structure in which a disc-shaped valve element 33 is fixed to the center of the diaphragm 31 by welding. In this heat-sensitive element 26, the mounting cylinder portion 13 of the second case body 23 is attached to the annular receiving groove 27 of the valve seat member 11.
And an elastic member 2 such as a spring plate interposed between the upper casing member 3 and the first case body 22.
The spring pressure 8 causes the valve seat member 11 to be pressed and fixed from above.

A spring member 50 such as a coil spring is interposed between the lower surface of the valve element 33 and the receiving groove 27. The spring member 50 is directed upward with respect to the valve element 33, that is, in the valve opening direction. Spring force is added. This spring force is, for example, when the pressure P1 of the primary fluid is 5 kgf / cm ² · g and the saturated vapor temperature of the primary fluid is 158 ° C., for example, the temperature of the thermal expansion medium 36 is 150 ° C. or more. When the temperature reaches 130 ° C., the valve is completely closed as shown in FIG. 6, and when the temperature becomes 130 ° C. or lower, the valve is completely opened as shown in FIG.
Of the thermal expansion medium 36 at the maximum pressure at which the primary side fluid can be trapped, for example, 16 kgf / cm ² · g. There is.

1 in the reference example not included in the present invention
The valve opening / closing operation due to the temperature change of the secondary fluid is performed by contracting the thermal expansion medium 36 that receives heat from the primary fluid, as in the first invention.
It is done by expansion.

Next, when the diaphragm 31 is damaged in the valve closed state of FIG. 6, the thermal expansion medium 36 is transferred to the heat sensitive chamber 35.
Leaks into the trap chamber 5 through the through hole 38 from the heat sensitive chamber 3
The pressure P3 in 5 falls to the pressure P1 of the primary fluid in the trap chamber 5. Therefore, the valve closing force acting on the valve body 33 due to the expansion of the thermal expansion medium 36 disappears, and the valve body 3
3 is the valve seat 1 due to the spring force applied from the spring member 50.
9 is separated from the seat 9, and the valve open state is maintained. If the diaphragm 31 is damaged when the valve is open, the spring member 5
With the spring force of 0, the valve open state is maintained.

In the reference example not included in the present invention, even if the diaphragm 31 is damaged and the pressures P1 and P3 in the trap chamber 5 and the heat-sensitive chamber 35 become the same, the valve element 33 is replaced by the spring member 50. Since the spring force of is directly applied, the valve can be surely opened. Further, the heat sensitive element 26 is simplified as compared with that of the first invention.

[ Third Invention] FIG. 7 is a vertical cross-sectional view showing a thermosensitive steam trap of the third invention in a valve open state, and FIG. 8 is a vertical cross-sectional view of the steam trap in a valve closed state. In this embodiment, the basic structure is the present invention.
5 and FIG. 6 which show reference examples not included in FIG. 5, and only different configurations will be described below.
In the valve body 33 of FIG. 7, a cylindrical base portion 33a fixed to the diaphragm 31 is integrally formed with a cylindrical portion 33b extending downward, and the cylindrical portion 33b is formed in an insertion hole formed in the valve seat member 11. 21 is slidably fitted and held in the vertical direction of FIG. The tubular portion 33b and the valve seat member 11
The seal member 54 is watertightly sealed between and. The base portion 33a of the valve body 33 is formed with a plurality of communication holes 29 that allow the internal passage 25 of the tubular portion 33b to communicate with the outside. Therefore, the internal passage 25 has the communication hole 2
The trap chamber 5 is always communicated with the trap chamber 5 through the through hole 38 provided in the second case body 23.

On the other hand, the valve seat member 11 has the cylindrical portion 33.
The valve seat 19 is integrally formed in a state where the lower end opening of the insertion hole 21 for slidably holding b is closed, and the side wall portion above the valve seat 19 communicates with the outlet 7 through the outlet passage 10. A plurality of outflow holes 51 are formed. An annular inflow path 52 is formed at the downstream end of the introduction path 9, and a filter member 53 for removing dust and the like is provided between the annular inflow path 52 and the trap chamber 5. .

[0054] The third valve operation due to a temperature change of the primary fluid in the invention, first, second invention and the present invention
The thermal expansion medium 36 receives heat from the primary fluid and contracts and expands, as in the reference example not included in FIG. In the valve open state of FIG. 7, the trap chamber 5 communicates with the outlet port 7 through the through hole 38, the communication hole 29, the internal space 25, the outflow hole 51, and the outlet passage 10. In the closed state, the lower end opening of the internal passage 25 of the valve element 33 is closed by the valve seat 19.

Next, when the diaphragm 31 is damaged in the valve closed state of FIG. 8, the thermal expansion medium 36 is transferred to the heat sensitive chamber 35.
Leaks into the trap chamber 5 through the through hole 38 from the heat sensitive chamber 3
The pressure P3 in 5 falls to the pressure P1 of the primary fluid in the trap chamber 5. At this time, the pressure in the internal space 25 of the valve body 33, which is in constant communication with the trap chamber 5, is kept the same as the pressure P1 of the primary fluid because it is blocked from the outlet 51 by the valve closed state. ing. That is,
When the heat-sensitive element 26 is damaged, the pressure P3 (= P1) in the heat-sensitive chamber 35 acting in the valve closing direction is canceled by the pressure P1 in the internal space 25, so that the valve body 33 is closed by a small fluid pressure. Only force works. As a result, the valve element 33 can be reliably opened by the slight spring force of the spring member 50, and the opened state can be maintained. When the diaphragm 31 is damaged in the valve open state, the thermal expansion medium 3
Due to the expansion of 6, the valve closing force acting on the valve element 33 disappears, and the spring force of the spring member 50 maintains the valve open state.

The third invention is not included in the present invention.
Similar to Reference Example, certainly becomes an open state by the spring force of the spring member 50 to the valve element 33 at the time of damage of sensitive heat element 26 is added thereto, also the valve element 33 the spring force of the spring member 50
The effect of a simple configuration can be obtained from the direct addition to the. Further, as described above, since the spring force of the spring member 50 can be small, the expansion force of the thermal expansion medium 36 of the heat-sensitive element 26 that overcomes this spring force to generate the valve closing force can also be small. And the pressure difference between the trap chamber (P3
-P1) does not become large. Therefore, the tire flam 31 interposed between the heat-sensitive chamber 35 and the trap chamber 5 is lightly loaded, and the durability is improved.

[Brief description of drawings]

FIG. 1 is a vertical cross-sectional view of a thermosensitive steam trap according to a first invention in a valve open state.

FIG. 2 (a) is a vertical cross-sectional view of the slam trap in the closed state, and FIG. 2 (b) is an enlarged view of part of (a).

FIG. 3 is a vertical cross-sectional view of a thermosensitive steam trap according to a second aspect of the present invention in a valve open state.

FIG. 4 is a vertical cross-sectional view of the above slam trap in a valve closed state.

FIG. 5 is a vertical cross-sectional view of a thermosensitive steam trap according to a reference example not included in the present invention in a valve open state.

FIG. 6 is a vertical cross-sectional view of the above slam trap in a valve closed state.

FIG. 7 is a vertical cross-sectional view of a thermosensitive steam trap according to a third invention in a valve open state.

FIG. 8 is a vertical cross-sectional view of the steam trap in the closed valve state.

─────────────────────────────────────────────────── ───Continued from the front page (56) References JP-A-4-370497 (JP, A) JP-A-5-71693 (JP, A) Actual development Sho 54-99132 (JP, U) (58) Field (Int.Cl. ⁷ , DB name) F16T 1/00

Claims (3)

(57) [Claims] 1. A casing is provided with an inlet for a primary fluid containing steam, an outlet for a secondary fluid containing condensate, and a trap chamber, and the trap chamber receives heat from the primary fluid. is arranged heat sensitive element having a thermal expansion medium, the thermosensitive element, the shape within the case, the intermediate portion have a inner space communicating with the outlet port when the valve is closed protrudes outward
And the bellows, the outer peripheral edge portion located outside of the bellows
A diaphragm fixed to the case, and the thermal expansion medium between the bellows and the diaphragm.
An enclosed space for enclosing is formed , and between the trap chamber and the outlet is formed in the diaphragm.
A thermosensitive steam trap in which a valve body for opening and closing is attached, and the bellows has a pressure receiving surface that receives a pressure that contracts when the valve is opened based on a pressure difference between the enclosed space and the inner space. 2. A casing is provided with an inlet for a primary fluid containing steam, an outlet for a secondary fluid containing condensate, and a trap chamber, and the trap chamber receives heat from the primary fluid. A heat-sensitive element in which a thermal expansion medium is enclosed between a cylindrical inner bellows and a cylindrical outer bellows is arranged, and a secondary passage that communicates with the outlet on one end side radially inward of the inner bellows. Is formed, and one end of the heat-sensitive element is supported by the casing, and the other end is provided with a valve body that opens and closes between the trap chamber and the secondary passage. A heat-sensitive steam trap having an inner diameter smaller than the effective diameter of the inner bellows and having a pressure receiving portion for receiving the pressure of the primary fluid in the valve opening direction. 3. A casing is provided with an inlet for a primary fluid containing steam, an outlet for a secondary fluid containing condensate, and a trap chamber, and further, heat received from the case and the primary fluid. Expansion medium ,
And an enclosed space for enclosing the thermal expansion medium between the case and the case.
A heat-sensitive element having a diaphragm that forms a space; a valve body attached to the diaphragm to open and close between the trap chamber and the outlet; and a spring member that applies a spring force to the valve body in a valve opening direction. A heat-sensitive steam trap, wherein the valve body is provided with an internal passage that is in constant communication with the trap chamber and that is opened and closed by the opening / closing operation of the valve body.