KR101381237B1 - Safety valve bypass device - Google Patents

Abstract

The present invention relates to an electrohydraulic safety valve opening/closing device. The frame of the opening/closing device of the present invention is formed by a body block (12). The body block (12) has an inlet passage (14), an outlet passage (14′), first and second flow rate passages (16,16′) extended in parallel with each other from the inlet passage (14), and an opening/closing passage (18) connecting the first and second flow rate passages (16,16′) and the outlet passage (14′) formed at the inside thereof. A flow rate setting valve (22) is mounted on the second flow rate passage (16′), and a passage opening/closing valve (24) is mounted on the opening/closing passage (18). The passage opening/closing valve (24) is operated by means of a solenoid (26), and the solenoid (26) produces excitation force in the state where power is supplied thereto, thus allowing the passage opening/closing valve (24) to close the opening/closing passage (18), while losing the excitation force in the state where power supply is cut, thus allowing the passage opening/closing valve (24) to open the opening/closing passage (18). A blocking unit (30) is disposed between the body block (12) and the safety valve (1). The blocking unit (30) serves to separate the body block (12) from the safety valve (1), without having any leakage of an operating fluid from the safety valve (1) in the state where the safety valve (1) is operated. Accordingly, the internal structure of the body block (12) is simple so that the operations are good, the manufacturing cost is reduced, the flow rate is easily adjusted to a desired value.

Description

Safety valve bypass device, electro-hydraulic

The present invention relates to an electro-hydraulic safety valve opening and closing device, and more particularly, an electro-hydraulic safety valve opening and closing device for operating a safety valve that blocks the internal pressure is higher than designed in the industrial boiler in the emergency situation in which the power supply is cut off. It is about.

As the industry develops, many industrial boilers are used. In industrial boilers, if the internal steam pressure increases above the designed value, it is discharged to prevent the boiler from exploding. For this purpose, a safety valve is used, but the safety valve does not operate properly when power is not supplied.

In such a situation that the pressure inside the boiler increases beyond the designed value in the state that power is not provided, the safety valve opening and closing device is to discharge the pressure inside the boiler to the outside by opening the safety valve. Such a safety valve opening and closing device is to open the safety valve in the situation that the power is not supplied to remove the pressure inside the boiler to prevent the boiler from exploding.

Conventionally used as such a safety valve opening and closing device has a number of components there is a problem that the internal configuration is relatively complicated, the cost increases.

In addition, the conventional safety valve opening and closing device has a problem that the configuration of adjusting the opening degree of the safety valve is an analog type, so that the opening degree of the safety valve cannot be accurately set.

Republic of Korea Patent No. 10-1085997 Republic of Korea Patent No. 10-0564338

An object of the present invention is to solve the conventional problems as described above, to provide a safety valve opening device having a relatively simple configuration.

Another object of the present invention is to provide a safety valve opening device that can accurately set the degree of opening the safety valve.

Still another object of the present invention is to replace a safety valve opening device in a state in which a boiler is operated in a safety valve opening device of a simple configuration.

According to a feature of the present invention for achieving the object as described above, the present invention is provided with an inlet flow passage and an outlet flow passage connected to the operation cylinder side of the safety valve through the first between the inlet flow passage and the outlet flow passage And a main body block having a second flow passage formed in parallel and an opening and closing flow passage formed between the first and second flow passages and the outlet passage, and installed on at least one side of the first flow passage and the second flow passage. And a flow rate setting valve configured to set the total flow rate, and a flow opening / closing valve installed in the open / close flow path to close the open / close flow path when the power is supplied, and open the open / close flow path when the power is cut off.

The flow path opening and closing valve is operated by a solenoid, the solenoid exerts an excitation force while the power is supplied to maintain the flow opening and closing valve closed the opening and closing flow path, and the solenoid is excited when the power is cut off Loss of force causes the flow path opening and closing valve to open and close the flow path.

A first flow rate setting port and a second flow rate setting port each having an orifice having a predetermined diameter are provided in the first flow path and the second flow path, respectively, to set the flow rate of the working fluid flowing through the first and second flow paths.

The flow rate setting valve lever for opening and closing the flow rate setting valve is rotatably installed on the outer surface of the body block to open and close the flow rate setting valve.

A blocking unit is further provided between the main body block and the safety valve. The blocking unit prevents leakage of the working fluid from the safety valve to the outside to separate the main body block during operation of the safety valve.

The blocking unit has a first blocking flow path that forms a frame and penetrates the inside and is connected to an inner side of the operation cylinder of the inlet flow path and the safety valve, and a second blocking flow path connected to the outside of the operation cylinder of the outlet flow path and the safety valve. It includes a blocking block is formed, and the first and second blocking valves respectively installed in the first and second blocking flow path to open and close.

In the electrohydraulic safety valve opening and closing device according to the present invention, the following effects can be obtained.

First, in the present invention, the internal configuration of the safety valve opening and closing device is relatively simple, so that the operation of opening the safety valve is performed more quickly and accurately and the manufacturing cost is lowered.

In the present invention, the opening degree of the safety valve can be set to a specific value, and in particular, the user can set the opening degree of the safety valve to a specific two value by allowing one of two flow paths to be opened and closed. Therefore, it is possible to easily set and use the open value according to the user's need, which also increases the user's convenience.

In addition, in the present invention, when the safety valve opening device is mounted on the safety valve, a blocking block is interposed between the safety valve and the main block to shield the flow path connected to the main block in the operating state of the boiler using the valve of the blocking block. To make it possible. Therefore, there is an effect that it is possible to replace the safety valve opening device in the operating state of the boiler.

1 is a perspective view showing a state in which a preferred embodiment of the safety valve opening device according to the present invention installed in the safety valve.
Figure 2 is an exploded perspective view showing the configuration of the safety valve opening device of the embodiment of the present invention.
Figure 3 is a side view showing the appearance configuration of an embodiment of the present invention.
4 is a cross-sectional view taken along line A-A 'of FIG. 3;
5 is a sectional view taken along the line B-B 'in Fig. 3;
6 is a hydraulic circuit diagram showing a hydraulic circuit configuration of an embodiment of the present invention.
Figure 7 is an explanatory view showing a path flowing through the first flow path in the embodiment of the present invention.
8 is an explanatory view showing a path flowing through the second flow path in the embodiment of the present invention.

Hereinafter, the configuration of a preferred embodiment of the safety valve opening device according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in the drawings, the safety valve (1) is to increase the safety of the industrial boiler by discharging the pressure to the outside when the steam pressure of the industrial boiler exceeds the set value. A valve housing 3 forms the exterior of the guide valve 1, and an operating cylinder (not shown) is installed therein. The actuating cylinder may be a double-acting cylinder used to move the piston therein in both directions within the actuating cylinder. The piston rod 5 connected to the piston protrudes out of the valve housing 3 and has a stem 7 at the tip. The stem 7 blocks the flow path through which the steam flows from the outside and communicates with the flow path during the operation.

The servo valve 9 is installed at one side of the outer surface of the valve housing 3. The servovalve 9 serves to control the hydraulic fluid for operating the piston of the actuating cylinder normally. That is, the hydraulic fluid is supplied to either one of the two sides partitioned by the piston from the working cylinder to cause the piston to move in a desired direction in the working cylinder, thereby causing the opening and closing operation of the stem 7.

On the other hand, the safety valve opening and closing device 10 of the embodiment of the present invention is mounted on the outer surface of the valve housing (3) of the safety valve (1). The safety valve opening and closing device 10 is to operate the piston of the operation cylinder to prevent the pressure inside the boiler rises above the set value in the state that the power supply is cut off.

The main body block 12 forms a skeleton of the safety valve opening and closing device 10. Flow passages are formed in the main body block 12, and an inlet flow passage 14 and an outlet flow passage 14 ′ are formed to open to one outer surface of the main body block 12. (See FIG. 6). 14 and the outlet flow passage 14 ′ are respectively connected to the inside of the operation cylinder. That is, it is connected to the space partitioned by the piston inside the working cylinder. For example, when the inlet flow passage 14 is connected to the rear end inner space partitioned by the piston, the outlet flow passage 14 'is a front end side partitioned by the piston (the side where the piston rod 5 is located). ) It is connected to the inner space.

A first flow passage 16 and a second flow passage 16 ′ are formed to be connected in parallel with the inlet passage 14 (see FIG. 6). The first flow passage 16 and the second flow passage ( 16 ') have different flow rates.

The first flow passage 16 and the second flow passage 16 ′ are both connected to the opening / closing passage 18. The opening and closing flow passage 18 is a portion in which the working fluid flowing along the first and second flow passages 16 and 16 'is combined.

First and second flow rate setting holes 20 and 20 'are respectively installed in the first flow path 16 and the second flow path 16'. Orifices of different sizes are formed through the flow rate setting ports 20 and 20 'to set the flow rates flowing along the respective flow passages 16 and 16'. For example, the first flow rate setting port 20 allows 10 liters per minute to flow, and the second flow rate setting port 20 'allows 20 liters per minute to flow. This depends on the size of the orifices formed in each.

On the other hand, a flow rate setting valve 22 is installed in the second flow path 16 '. Of course, the flow rate setting valve 22 does not necessarily have to be installed in the second flow path 16 '. It may be installed in the first flow path (16). When the flow rate setting valve 22 is installed in the second flow path 16 ′, the safety valve opening and closing device 10 of the present invention has a capacity equal to the flow rate of the first flow path 16 or the first flow path. It has a capacity equal to the sum of the flow rates of the first flow path 16 and the second flow path 16 '. If the first and second flow rate setting holes 20 have the flow rates as described above, respectively, the capacity may be set to 10 liters per minute and 30 liters per minute, respectively.

Reference numeral 22 'serves to shield the space in which the flow rate setting valve 22 is installed from the outside. This is because the flow rate setting valve 22 is installed in a space formed inside the body block 12.

The opening and closing operation of the flow rate setting valve 22 is performed by the flow rate setting valve lever 23 exposed to the outer surface of the main body block 12. The operator rotates the flow rate setting valve 22 with a hand or a tool to perform the opening and closing operation of the flow rate setting valve 22. When the flow rate setting valve lever 23 is rotated to one side, the flow rate setting valve 22 is opened, and when the flow rate setting valve lever 23 is rotated to the other side, the flow rate setting valve 22 is closed. It becomes a state.

The opening and closing flow path 18 is provided with a flow path opening and closing valve 24. The flow path opening and closing valve 24 is to block or open the flow of the working fluid through the safety valve opening and closing device 10 of the present invention, the flow of the working fluid is normally blocked, but in case of emergency In the state, the opening and closing flow path 18 is opened. The flow path open / close valve 24 uses a push-pull poppet valve, which is driven by the solenoid 26 to open or close the open / close flow path 18. In the hydraulic circuit diagram of FIG. 6, the flow path opening / closing valve 24 opens the opening / closing flow path 18.

Pressure sensors 28 are provided at the inlet flow passage 14 side and the outlet flow passage 14 ', respectively, to measure the pressure.

The blocking unit 30 is provided separately from the main body block 12. The blocking unit 30 is to block the working fluid from falling out of the working cylinder of the safety valve (1). That is, when the main body block 12 of the present invention is separated from the safety valve 1 for maintenance, the boiler or safety valve 1 can be operated without stopping the driving.

The blocking block 30 forms the skeleton of the blocking unit 30. The blocking block 30 has a rectangular parallelepiped shape in this embodiment, and the first blocking channel 32 and the second blocking channel 32 ′ are formed through the inside of the blocking block 30. The first blocking flow path 32 is connected to the inlet flow path 14 of the main body block 12 and the inner side of the piston rod 5 of the operation cylinder of the safety valve 1. The second blocking passage 32 'is connected to the outlet passage 14' of the main body block 12 'and the piston rod 5 side of the operation cylinder of the safety valve 1.

The first blocking passage 32 is provided with a first shutoff valve 34. The first shutoff valve 34 serves to close the first blocking flow path 32 when necessary. That is, when the first blocking valve 34 maintains the first blocking flow path 32 in an open state and needs to replace the body block 12, the first blocking flow path 32 is closed. Do not allow working fluid to be discharged to the outside.

A second blocking valve 34 'is installed in the second blocking flow path 32'. The second shutoff valve 34 'serves to close the second blocking flow path 32' when necessary. When the main block 12 needs to be replaced, such as the first shutoff valve 34 above, the second blocking flow path 32 is closed to prevent the working fluid from being discharged to the outside.

The first and second blocking levers 36 and 36 'for manipulating the first and second shut-off valves 34 and 34' are exposed to the outer surface of the blocking block 31 so that the operator may manually Can be rotated easily.

Hereinafter, the safety valve opening and closing device according to the present invention having the configuration as described above will be used in detail.

Safety valve opening and closing device 10 of the present invention is mounted on the outer surface of the safety valve 1 as shown in FIG. This is to allow the safety valve 1 to be opened in an emergency in which power is cut off by the rest even if one or two safety valve opening and closing devices 10 of the plurality fail.

The safety valve 1 is usually operated by the drive of the servo valve (9). That is, the servo valve 9 supplies the working fluid to the working cylinder inside the safety valve 1 so that the piston moves and the inlet and out of the piston rod 5 are made. Since the actuating cylinder is double acting, the direction of movement of the piston is determined by which of the actuating fluids is supplied to the inside of the actuating cylinder partitioned by the piston.

On the other hand, the safety valve opening and closing device 10 is a state in which the power supply opening and closing valve 24 is pushed by the solenoid 26 as shown in Figure 9 in the state that power is supplied to close the opening and closing flow path 18 Keep it. At this time, the first and second blocking flow paths 32 and 32 'are in an open state, and the open / closed state of the flow rate setting valve 22 is determined according to the capacity of the safety valve opening and closing device 10. Since the flow path opening and closing valve 24 is in the state of closing the opening and closing flow path 18, the working fluid does not flow through the safety valve opening and closing device 10. However, as described above, the operation of the safety valve 1 is performed by driving the servovalve 9.

When the industrial boiler is normally operated and the power is cut off, power is also not supplied to the safety valve opening and closing device 10. For reference, the servovalve 9 does not operate when the power is cut off. When power is not supplied to the entire boiler, power is not supplied to the solenoid 26, so that the solenoid 26 loses an excitation force, and the flow path opening and closing valve 24 is provided by a restoring force of an elastic member (not shown). ) Becomes a state as shown in FIG. That is, the flow path opening and closing valve 24 opens the opening and closing flow path 18.

In such a state, the working fluid can flow through the opening and closing flow path 18. When the working fluid flows through the opening and closing flow path 18, when the pressure inside the boiler is applied to the stem 7, the stem 7 is moved by the internal pressure so that the piston It will move within the working cylinder. In other words, the piston rod 5 is moved in the direction entering the working cylinder.

Therefore, the working fluid in the inner space opposite the piston rod 5 in the working cylinder does not move toward the servovalve 9 and moves to the safety valve opening and closing device 10 in which the opening and closing flow path 18 is opened. .

That is, it passes through the first blocking passage 32 and enters the inlet passage 14. The inlet passage 14 passes through the first and / or second flow passages 16 and 16 'and passes through the opening and closing passage 18 and the outlet passage 12 to the second blocking passage 32'. Goes.

The working fluid passing through the second blocking flow path 32 ′ enters into the working cylinder of the safety valve 1. In this operation, the safety valve 1 does not operate when the pressure acting on the stem 7 is lower than or equal to a predetermined value, but the pressure within the boiler is higher than a predetermined level so that the stem 7 can be operated. When the internal pressure is discharged to the outside to prevent the industrial boiler from exploding.

Meanwhile, the flow rate of the working fluid passing through the first flow path 16 and the second flow path 16 'is determined as follows. When the flow rate setting valve 22 provided in the second flow path 16 'is opened, the sum of the flow rates set by the first flow rate setting port 20 and the second flow rate setting port 20' is total. When the flow rate is set and the flow rate setting valve 22 is closed, the flow rate set by the first flow rate setting port 20 becomes the total flow rate. The operation of the flow rate setting valve 22 is made by rotating the flow rate setting valve lever 23 as described above.

Next, when any one of the components provided in the main body block 12 is damaged and needs to be replaced, the first and second shutoff valves 34 and 34 'of the blocking unit 30 are locked to the first. And blocking the flow of the working fluid through the second blocking flow paths 32 and 32 '. This is because the operating fluid inside the safety valve 1 does not come out when it is in such a state. In this state, the main body block 12 may be removed and replaced with another one, and the first and second blocking flow paths 32 and 32 'may be opened again. Opening the first and second blocking flow paths 32 and 32 'opens the first and second blocking valves 34 and 34' by rotating the first and second blocking levers 36 and 36 '. Just do it.

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

For example, although spherical ball valves were used as the first and second shut-off valves 34 and 34 ', they may be replaced by shaft ball valves.

In the illustrated embodiment, the flow rate setting valve 22 is installed only in the second flow path 16 ', but the flow rate setting valve 22 is respectively provided in the first flow path 16 and the second flow path 16'. Is installed or the flow rate setting valve 22 may be installed only in the first flow path (16). When the flow rate setting valve 22 is provided in both the first and second flow paths 16 and 16 ', the flow rate can be set to more various flow rates.

1: safety valve 3: valve housing
5: piston rod 7: stem
9: Servovalve 10: Safety valve switchgear
12: main body block 14: inlet flow path
14 ': Exit Euro 16: First Flow Euro
16 ': 2nd flow path 18: opening and closing flow path
20: first flow rate setting mouth 20 ': second flow rate setting mouth
22: flow rate setting valve 24: flow path opening and closing valve
26: solenoid 28: pressure sensor
30: blocking unit 31; Blocking Block
32: first blocking euro 32 ': second blocking euro
34: 1st shutoff valve 34 ': 2nd shutoff valve

Claims (6)

An inlet flow passage and an outlet flow passage connected to an operation cylinder side of the safety valve are provided therein, and first and second flow passages are formed in parallel between the inlet flow passage and the outlet flow passage, and the first and second flow passages A main body block having an opening and closing flow path formed between the outlet flow paths,
A flow rate setting valve installed on at least one side of the first flow path and the second flow path to set the total flow rate;
Electro-hydraulic safety valve opening and closing device that is installed in the opening and closing flow path comprising a flow path opening and closing valve for closing the opening and closing flow path in the power supply state and the power supply is cut off the opening and closing flow path.
According to claim 1, wherein the flow path opening and closing valve is operated by a solenoid, the solenoid exerts an excitation force in the state that power is supplied to maintain the flow path opening and closing valve closed the opening and closing flow path and the power is cut off And the solenoid loses an excitation force so that the flow path opening and closing valve opens and closes the opening and closing flow path.
2. The working fluid of claim 1, wherein the first flow path and the second flow path are provided with a first flow rate setting port and a second flow rate setting port each having an orifice having a predetermined diameter. Electro-hydraulic safety valve switchgear to set the flow rate of the gas.
2. The electrohydraulic safety valve opening and closing device according to claim 1, wherein the flow rate setting valve lever for opening and closing the flow rate setting valve is rotatably installed on an outer surface of the main body block to open and close the flow rate setting valve.
According to any one of claims 1 to 4, a blocking unit is further provided between the main body block and the safety valve, the blocking unit to block the leakage of the working fluid to the outside from the safety valve to the main body block Electro-hydraulic safety valve opening and closing device for disengagement of safety valve during operation.
The blocking unit of claim 5, wherein the blocking unit forms a skeleton and penetrates through the inside to be connected to an inner side of the inlet passage and an operation cylinder of the safety valve, and an outer side of the operation cylinder of the outlet passage and the safety valve. An electro-hydraulic safety valve opening / closing device comprising a blocking block having a second blocking passage connected thereto, and first and second shut-off valves respectively installed on the first and second blocking passages to open and close.

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