KR0119642B1 - Unloading type governer - Google Patents

Abstract

None.

Description

No-load type pressure regulator

1 is an embodiment of the unloading type regulator (Unlooding Type Governer) according to the present invention.

2 and 3 are exemplary embodiments integrating a supply line, a bypass line, and a pilot regulator.

4 is an explanatory diagram of a conventional no-load type regulator.

* Explanation of symbols for main parts of the drawings

1: Main regulator (static regulator) 2: Lower chamber

3: control room 4: main diaphragm

4a: main spring 5: main valve

6 Spindle 9 Supply Orifice

11: primary pressure line 12: bypass line

13: bypass valve 14: pilot regulator

15: pilot diaphragm 15a: pilot spring

16: lower chamber 17: upper chamber

18: detection line 19: pilot valve

20: Blyde Orifice 21: Pilot Spindle

22: bleed line 23: interlocking line

a: Gas passage P1: Primary pressure

P2: secondary pressure

The present invention relates to a no-load type pressure regulator as a pressure regulator (static regulator) used to maintain a constant supply gas pressure.

A conventional no-load type pressure regulator is shown in FIG. 4 and the principle of operation is described. When the flow rate Q on the secondary side increases, the secondary pressure P2 decreases, and the decrease in the P2 causes the pilot regulator 01 to decrease. By sensing, the pilot valve (bleed orifice) 02 increases the flow rate q of the bleed line 03.

When q increases, the differential pressure ΔP before and after the supply orifice 05 installed in the supply line 04 increases, and the control pressure Pc (P1-ΔP) acting on the control chamber 06 of the main regulator 07 is increased. Is reduced, the main diaphragm 08 is displaced toward the control chamber 06 to open the main valve 09 to maintain P2 at a constant pressure.

As described above, in the conventional no-load type pressure regulator, the supply orifice 05 is fixed, and the pilot valve 02 is variable according to the secondary pressure.

The larger the diameter of the pilot valve 02 with respect to the supply orifice 05 is, the larger the pressure drop in the control chamber 06 is, and the maximum flow rate and offset (the amount of decrease in the secondary pressure due to the increase in flow rate) and the like. Since the static characteristics are good, the diameter of the supply orifice 05 is set as small as possible.

For this reason, when secondary pressure P2 falls rapidly, the pilot valve 02 opens rapidly and the flow volume of the pilot line 03 increases, and the differential pressure before and behind the supply orifice 05 can be taken large. As a result, the control pressure in the control chamber 06 was lowered sufficiently fast, the main valve 09 opened quickly enough, and the recovery of the secondary pressure P2 could be accelerated.

On the other hand, however, if the secondary pressure P2 rises sharply, even if the pilot valve 02 is closed rapidly, since the diameter of the supply orifice 05 is small, the primary pressure P1 in the control chamber 06 is reduced. It takes a long time to apply, and since the main valve 09 is not closed during that time, the secondary pressure P2 rises and there is a problem that the recovery to the set pressure is delayed.

In addition, when the diameter of the supply orifice 05 is made, the splice line 04 is closed when the blockage of the back occurs first or when the part of the supply orifice 05 is frozen during the winter. There is a fear that the control pressure in the control chamber 06 is extremely lowered, the main valve 09 opens, and the secondary pressure P2 is abnormally raised.

An object of the present invention is to provide a recovery of the secondary pressure in a short time when the secondary pressure is rapidly increased in the no-load type pressure regulator, and even when the supply line is closed by freezing the supply orifice. The secondary pressure does not rise abnormally.

The configuration of the present invention proposed in order to realize the above object is as follows.

In the no-load type pressure regulator, a bypass line for bypassing the supply orifice installed on the supply line communicating the primary pressure side and the control chamber of the main regulator is provided, and a bypass valve is attached to the bypass line. At the same time, the bypass valve was opened when the secondary pressure rose above the set pressure to open the bypass line to rapidly introduce the primary pressure into the control chamber.

As described above, a bypass line for bypassing the supply orifice is provided, and when the bypass line is opened when the secondary pressure rises above the set pressure, a large amount of gas enters the control room through the bypass line at once. The pressure in the control room can approach the primary pressure in a short time.

As the pressure in the control room approaches the primary pressure, the main valve acts in the immediate closing direction from the main spring to suppress the rise of the secondary pressure.

When the supply line is closed due to freezing of the supply orifice, gas does not flow into the control chamber, but the main valve is closed by introducing a primary pressure through the bypass line in the control chamber, thereby reducing the secondary pressure (P2). Can be prevented from rising abnormally.

Example 1

Figure 1 shows an embodiment of the present invention, 1 is a main regulator, the main regulator (1) is partitioned up and down the main diaphragm (4) inside the primary pressure (P1) to the primary pressure line (11) The control chamber 3 which introduces the lower chamber 2 which introduces via diesel gas, the primary pressure P1 via the supply line 9 which installed the supply orifice 10 in the middle, and the main diaphragm 4 It consists of the main spring 4a which adds the force to the lower side, and the main valve 5 attached to the lower end of the spindle 6 which protrudes downward from the main diaphragm 4.

The gas passage a has the main valve 5 as its boundary, and the upstream side is the primary pressure P1 side and the downstream side is the secondary pressure P2 side.

12 is a bypass line provided in the supply line 9 so as to bypass the supply orifice 10. The bypass line 12 has a bypass valve 13 attached thereto.

14 is a pilot regulator. The pilot regulator 14 is divided into a lower chamber 16 and an upper chamber 17 by a pilot diaphragm 15 added to the lower side by a pilot spring 15a. The secondary pressure P2 is introduced into the path via the detection line 18.

19 is a pilot valve for opening and closing the bleed line 22 connecting the control room 3 and the secondary pressure (P2) side of the main regulator (1), 20 is the bleeding orifice, 21 is a pilot regulator (14) The pilot diaphragm 15 and the pilot valve 19 are connected, and when the pilot valve 19 moves upward and closes, and the pilot diaphragm 15 moves upward, the pilot valve 19 The pilot spindles 23, which are configured to move upwards, are also connected to the bypass valve 13 to transfer the operation of the pilot spindles 21 to the bypass valve 13. When 19) is closed and the secondary pressure rises further, the pilot spindle 21 is further moved, and is adjusted to transmit the shift to the bypass valve 13 to open.

2 shows an embodiment in which the supply line 9, the supply orifice 10, the bypass line 12, the bypass valve 13, and the pilot regulator 14 are integrally formed. FIG. 3 shows the supply line. Another embodiment other than the integrated configuration of FIG. 2 in which (9) and bypass line 12 are separately configured is shown.

The above-described embodiment will be described next.

(1) When operating normally

The no-load type pressure regulator is a gas constant pressure regulator used for the purpose of adjusting the secondary pressure P2.

When the current secondary pressure P2 is lower than the set pressure, the pressure in the lower chamber 16 of the pilot regulator 14 is lowered via the detection line 18, and the diaphragm 15 is lowered by the pilot spring 15a. The position shifts toward the insolate chamber 16. When the diaphragm 15 is moved downward, the pilot spindles 21 push the pilot valve 19 to open the bleed-olipos 20. When the bleed orifice 20 is opened, the pressure in the control chamber 3 of the main regulator 1 decreases, and the main diaphragm 4 is controlled by the primary pressure P1 introduced into the lower chamber 2. It moves to the upper side of the control chamber 3 as much as the pressure lowered in the inside. When the main diaphragm 4 moves upward, this position shift is transmitted from the spindle 6 to the main valve 5, and the main valve 5 opens to increase the flow rate of the gas flowing to the secondary side P2. The secondary pressure rises (recovers).

On the contrary, when the secondary pressure P ₂ rises above the set pressure, the secondary pressure P ₂ decreases (recovers) by the reverse process of the above-described process.

By this operation, the secondary pressure P2 is stabilized.

(2) When secondary pressure rises abnormally

Next, the case where the secondary pressure P2 rises rapidly will be described. The operation in the case where the secondary pressure suddenly rises is the same as above, and the pilot regulator 14 is operated so that the pilot valve 19 closes the blade orifice 20. When the bleed orifice 20 is closed, the pressure in the control chamber 3 gradually rises due to the gas inflow on the primary side flowing from the supply orifice 10, but the bypass line is caused by an abnormal rise in the secondary pressure above the set pressure. Since the bypass valve 13 of (12) is opened, a large amount of gas flows into the control chamber 3 via the bypass line 12, rapidly approaching the inside of the control chamber 3 to the primary pressure P1. do. When the pressure in the control chamber 3 approaches the primary pressure P1, the main spring 4a pushes down the main diaphragm 4 to close the main valve 5, thereby quickly avoiding an abnormal rise of the secondary pressure P2. .

(3) When the supply orifice 10 is blocked (by freezing or dust, etc.)

The supply orifice 10 is preferably a diameter as small as possible in order to improve static characteristics, but when the diameter is small, it is easy to be clogged. If it is blocked, since the primary pressure P1 is not introduced into the control chamber 3, the pressure in the control chamber 3 is lowered and the pressure difference from the lower chamber 2 side is increased, and the main valve 5 is operated only in the open side. .

As a result, the secondary pressure is excessively increased. However, as in the case of the above operation (when the secondary pressure is abnormally increased), the bypass valve 13 is once opened when the secondary pressure P2 becomes higher than the set pressure. Since the primary pressure is applied to the control chamber 3 via the bypass line 12, the main diaphragm 4 closes the main valve 5 to suppress abnormal rise of the secondary pressure P2.

2, the gas from the primary side reaches the control chamber 3 side via the supply line 9 provided in the bypass valve 13 in the normal state.

In addition, the pilot valve 19 interlocked with the pilot diaphragm 15 does not push up the bypass valve 13 only when the secondary pressure P2 fluctuates within a pressure range not exceeding the set pressure. When the differential pressure P2 rises above the set pressure, the pilot valve 19 pushes the bypass valve 13 and opens the bypass line 12. As a result, the primary pressure P1 is applied to the control chamber 3 from the bypass line 12 side.

In addition, said operation is the same also about the Example shown in FIG.

The present invention provides a bypass line 12 for bypassing the supply orifice 10 as described above, and opens the bypass line 12 when the secondary pressure P2 rises above the set pressure. Since the differential pressure P1 is rapidly applied in the control chamber 3, the following effects are obtained.

First, since the pressure in the control chamber 3 rises rapidly, the main diaphragm 4 can be immediately operated to the closing side.

As a result, abnormal rise of the secondary pressure P2 can be prevented quickly.

Second, even when the supply line 12 is closed due to freezing of the supply orifice 10, the primary pressure P1 can be introduced into the control chamber 3 by the opening of the bypass line 12. The valve 5 can be operated to prevent abnormal rise in the secondary pressure P2.

Claims (1)

Bypass line 12 for bypassing the supply orifice 10 installed in the supply line 9 communicating with the primary pressure P1 side and the control chamber 3 of the main regulator 1 is provided. In the bypass line 12, the bypass valve 13 that is normally closed is installed, and when the secondary pressure P2 rises above the set value, the bypass valve 13 is opened to bypass the bypass valve. A no-load type pressure regulator configured to open a pass line (12) and to rapidly introduce a primary pressure (P1) into the control chamber (3).

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