JP2000172344A - Pressure controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make the constitution of a pressure setting part supplying pilot pressure adjusted by a control part to a pressure control valve and controlling secondary pressure to be compact. SOLUTION: A pressure controller 11 is formed of a pressure control valve 14, a pilot valve 16, a pressure setting part 17 and a control circuit 18. The pressure setting part 17 is fitted below the pilot valve 16 so that it can be attached/detached and the pressure setting device 10 is integrally constituted. Since the pressure setting part 17 can be attached to/detached from the pilot valve 16, an existing pilot valve can easily be improved. The control circuit 18 and an electric motor 51 are stored in the same explosion proof case 46 and the pressure setting part 17 is constituted. Thus, it is not necessary to pull out a signal cable 72 which electrically connects the control circuit 18 with the electric motor 51 to an outer part and a cable wiring work using an explosion proof conduit can be reduced or eliminated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pressure control device, and more particularly, to a pilot pressure (control pressure of a pressure setting unit) adjusted by a control circuit, which is supplied to a driving unit of the pressure control valve to downstream of the pressure control valve. The present invention relates to a pressure control device for controlling a pressure (secondary pressure) of the pressure control device to a set pressure.

[0002]

2. Description of the Related Art For example, in a pressure control device installed in a line for supplying city gas, a diaphragm that operates using pressure is employed as a drive unit of the pressure control valve, and a pilot valve is operated by the pressure control device. The pressure (secondary pressure) on the downstream side of the pressure control valve in the gas supply line is set by adjusting the pilot pressure (control pressure) supplied from the pilot valve to the diaphragm chamber of the pressure control valve by operating the valve section of The pressure value (target pressure) is set.

A pressure control device of this type is disclosed, for example, in Japanese Utility Model Publication No. Hei 5-17685. The pressure control device described in this publication includes a pressure control valve for controlling a secondary pressure of gas supplied to a downstream pipe, a pilot valve for adjusting a control pressure supplied to an actuator of the pressure control valve, and a pressure control valve. A remote setter (pressure setter) having a motor for operating the valve portion of the pilot valve so that the secondary pressure becomes a predetermined set pressure value; And a control circuit that drives and controls the motor of the remote setter so that the set pressure value is obtained for each.

In the operation of the remote setter when the pressure setting is changed, there is a proportional relationship between the resistance value of a potentiometer provided in the remote setter and the secondary pressure controlled by the pressure control valve. Therefore, the control circuit controls the remote setter so that the potentiometer resistance value of the remote setter becomes the set pressure based on the characteristics of the potentiometer resistance value and the secondary pressure set in the control device that controls the remote setter using this proportional relationship. Drive.

[0005] Since the gas consumption varies depending on each time zone of each month and day, the control circuit moves the motor of the remote setter to the step-up side or the step-down side in accordance with the control data registered in advance in the memory. While driving, the potentiometer resistance value is controlled as a feedback signal. Further, the pressure control valve and the remote setter are installed in a city gas piping line, whereas the control circuit is installed in a management office or the like remote from the installation site of the pressure control valve and the remote setter.

[0006] Further, as a pressure control device having a different structure from the above, for example, a mainspring-type pressure setter is used instead of the remote setter, and the valve portion of the pilot valve is operated using the mainspring as a drive source. There is a method.

[0007]

In the above-mentioned conventional pressure control device, the motor of the remote setter is driven so that the pressure is set by the control circuit, and the valve portion of the pilot valve is driven to drive the pressure control valve. Since the pilot pressure supplied to the diaphragm chamber is controlled and a remote setter having an electric motor is installed near the pressure control valve,
The remote setter must have a flameproof structure.

On the other hand, a control circuit for driving and controlling the motor of the remote setter is often installed in a management office or the like that is remote from the installation location of the pressure control valve. Therefore, when installing the pressure control valve, it is necessary to wire the signal cables (up to 13) connected to the remote setter to the place where the control circuit is installed, and the signal cables also have an explosion-proof structure. Must be inserted through a metal pipe. Therefore, in the case of the conventional pressure control device, there is a problem that much labor and time are required to perform this wiring work.

[0009] In the pressure control device having the above-mentioned spring-type pressure setting device, there is a problem that a regular worker needs to wind the mainspring and maintenance work after installation is troublesome. Therefore, an object of the present invention is to provide a pressure control device that solves the above problem.

[0010]

In order to solve the above problems, the present invention has the following features. The invention according to claim 1 is a pressure control valve that is provided in the middle of a pipe through which a fluid flows and controls a downstream pressure to a constant set pressure, and a pressure that controls a set pressure of the pressure control valve to a predetermined pressure. In a pressure control device including a setting unit, a pressure adjustment unit that adjusts a set pressure of the pressure control valve, and a pressure setting spring provided in the pressure adjustment unit is increased or decreased to set the pressure control valve. A drive unit for changing the pressure, and a control unit for controlling the drive unit to set the spring load of the pressure setting spring to a predetermined set pressure, wherein the drive unit and the control unit are in one case. It is characterized by being stored in.

Therefore, according to the first aspect of the present invention, since the drive unit and the control unit are housed in one case, a signal cable for electrically connecting the drive unit and the control unit is provided. This eliminates the need for wiring work or simplifies the wiring work, so that the time required for installation work can be shortened by saving the labor for installation work. Further, the invention according to claim 2 is characterized in that the pressure adjusting unit and the case in which the driving unit and the control unit are housed are detachable.

Therefore, according to the second aspect of the present invention, since the pressure adjusting section and the case in which the driving section and the control section are housed are detachable, the driving section and the control section housed in the case are separated. It can be handled as one unit, so that mounting and disassembling operations can be easily performed, and maintenance operations can be easily performed.

[0013]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a configuration diagram of an embodiment of the pressure control device according to the present invention. As shown in FIG.
A pressure control device 11 having a pressure setting device 10 is disposed between an upstream pipe 12 and a downstream pipe 13 for supplying city gas. The pressure control device 11 regulates a pressure control valve 14 for controlling a secondary pressure of gas supplied to the downstream pipe 13 and a pilot pressure (control pressure) supplied to an actuator 15 of the pressure control valve 14. (Pressure adjusting unit) 16, a pressure setting unit 17 for operating the valve unit of the pilot valve 16 so that the secondary pressure becomes a predetermined set pressure value, and a pre-registered and built-in pressure setting unit 17. And a control circuit (control section) 18 for controlling the pressure setting section 17 so that the secondary pressure becomes a set pressure value for each time zone based on the control data.

The pressure setting device 10 includes a pilot valve 1
6 and a pressure setting unit 17 incorporating a control circuit 18. Therefore, the pressure setting unit 17 controls the control circuit 1
Wiring work for drawing out a signal cable electrically connected to the cable 8 to the outside is unnecessary or can be largely reduced, and the wiring work can be performed in advance in an assembly process in a factory or the like. Further, when only the control unit is replaced by using the already installed pressure control valve 14 as it is, since the pressure setting unit 17 is simply attached to the existing pilot valve as described above, the existing pressure control valve 14 can be easily replaced. Can be improved.

Actuator section 15 of pressure control valve 14
Has an upper diaphragm chamber 20 and a lower diaphragm chamber 21 defined by a diaphragm 19, and a pressure setting spring 22 for pressing the diaphragm 19 in a valve closing direction is disposed in the upper diaphragm chamber 20. I have.
The pilot valve 16 is connected to the 1
2 connected to the next pressure introduction pipe 23 and the downstream pipe 13
The secondary pressure introduction pipeline 25 connected to the lower pressure chamber 24, the pilot pressure introduction pipeline 25 connected to the lower diaphragm chamber 21, and the secondary pressure introduction pipeline 26 connected to the upper diaphragm chamber 20 are connected.

The amount of compression of the pressure setting spring 36 of the pilot valve 16 is increased or decreased by the operation of the pressure setting section 17, and the load of the pressure setting spring 36 is increased or decreased by the increase or decrease of the compression amount. Set pressure P _s of the pilot valve 16, the secondary pressure is applied to the load and the diaphragm 32 of the pressure setting spring 36 P ₂
Becomes the secondary pressure P ₂ when the forces due to are balanced. Therefore, the pilot valve 16 increases or decreases the set pressure P _s by increasing or decreasing the spring load of the pressure setting spring 36 by the operation of the pressure setting section 17. Here, for example, when the secondary pressure P ₂ becomes lower than the set pressure P _s , the spring load of the pressure setting spring 36 becomes larger than the force due to the secondary pressure P ₂ applied to the diaphragm 32, so that the diaphragm 32 is displaced upward. I do. As a result, the valve portion of the pilot valve 16 opens to increase the pilot pressure.

On the other hand, a pilot pressure is introduced into the lower diaphragm chamber 21 from the pilot valve 16 via a pilot pressure introduction pipe 25, and the upper diaphragm chamber 20
To the secondary pressure P ₂ via the secondary pressure introduction pipes 24 and 26.
Has been introduced. Therefore, as the pilot pressure increases, the lower diaphragm chamber 21 and the upper diaphragm chamber 20
The diaphragm 19 is displaced upward with respect to the load of the pressure setting spring 22 due to the pressure difference.

As a result, the valve portion of the pressure control valve 14 is opened.
Operate and secondary pressure P_TwoSet pressure P _sTo rise. Ma
Secondary pressure P_TwoIs the set pressure P_sAs it rises, the pressure
The spring load of the setting spring 36 is applied to the diaphragm 32.
Secondary pressure P_TwoDiaphragm force
The ram 32 is displaced downward. This allows the pilot valve
The sixteen valve units perform valve closing operations to reduce the pilot pressure.
Therefore, the pilot pressure drops and the lower diaphragm
Pressure difference between the diaphragm chamber 21 and the upper diaphragm chamber 20 is reduced.
Therefore, it is displaced downward by the load of the pressure setting spring 22.
You. As a result, the valve portion of the pressure control valve 14 performs a valve closing operation.
Secondary pressure P_TwoSet pressure P_sTo step down.

As described above, when the secondary pressure P ₂ fluctuates due to a change in the amount of gas used on the downstream side, the diaphragm 19 of the pressure control valve 14 is displaced as described above, and the secondary pressure P ₂ becomes the set pressure value. controlling the pressure to keep the P _s. here,
The pressure setting unit 17 will be described. FIG. 2 is an enlarged longitudinal sectional view showing the internal configuration of the pressure setting device 10. Also,
FIG. 3 is a side view of the pressure setting device 10.

As shown in FIGS. 2 and 3, the pressure setting device 10 includes a pressure setting portion 17 below the pilot valve 16.
Is detachably attached. The housing 31 of the pilot valve 16 includes an upper portion 31a, a middle portion 31b, and a lower portion 31.
and c are integrally fastened by bolts 30 in a state of being overlapped. The inside of the housing 31 is formed by an upper diaphragm 32 and a lower diaphragm 33 in the upper chamber 3.
4a, a middle chamber 34b, and a lower chamber 34c.

The lower chamber 34c is provided with a pressure setting spring 36 for pressing the lower diaphragm 33 upward. The pressure setting spring 36 has a lower end portion in contact with a disk-shaped spring receiver 37 screwed with the adjusting screw 55 and an upper end portion in contact with a spring receiver 38 fixed to the lower surface of the lower diaphragm 33. The pressure setting spring 36 sets the set pressure value P _s is the spring force is adjusted by the motor driving force as described later.

The housing 31 of the pilot valve 16
An explosion-proof case 46 having a pressure-resistant explosion-proof structure of the pressure setting unit 17 is detachably attached to the lower part of the pressure setting unit 17 by fastening bolts 47. This explosion-proof case 46 is used for the upper case 4
8 and the lower case 49 are combined, and are fixed to each other by fastening bolts 50. Inside the explosion-proof case 46, an electric motor 51 for adjusting the spring force of the pressure setting spring 36, a speed reducer 52 for reducing the rotation of the electric motor 51, and a rotation to which the rotation from the speed reducer 52 is transmitted. Shaft 53, upper end of rotating shaft 53 and coupling 54
Adjusting screw 55 coaxially connected via
A potentiometer 56 composed of a variable resistor for measuring the rotational position of No. 3, an auxiliary battery 57, and a control circuit 18 for controlling the driving of the electric motor 51 based on the measured value from the potentiometer 56 are accommodated.

FIG. 4 is a block diagram of each electronic device housed in the explosion-proof case 46. As shown in FIG. 4, the control circuit 18 is conventionally provided at a location remote from the installation site. However, in the present embodiment, the control circuit 18 is housed in the same explosion-proof case 46 as the electric motor 51 and is compact. It has a configuration. Therefore, a signal cable 72 for electrically connecting between the control circuit 18 and the electric motor 51, a signal cable 73 for electrically connecting between the control circuit 18 and the potentiometer 56, and the control circuit 18 and the auxiliary battery 57
It is not necessary to draw out the cable 74 for electrically connecting the cables to the outside, and it is not necessary to insert the cables 72 to 74 into explosion-proof pipes or the like.

Therefore, the troublesome wiring work as in the related art is not required, and the installation work can be performed easily, and the installation work time can be shortened. Further, unlike a pressure control device having a mainspring type pressure setting device, an operator does not need to periodically wind the mainspring, thereby simplifying maintenance work after installation. Also, as described above, the explosion-proof case 4
6 is detachably attached to the lower portion of the housing 31 of the pilot valve 16 by fastening a bolt 47, so that inspection can be easily performed by separating the pilot valve 16 from the housing 31 of the pilot valve 16 even during inspection or the like. As a result, the maintainability of the control circuit 18 is improved.

Further, the pressure setting section 17 is provided in the explosion-proof case 4 where the same devices as the control circuit 18 and the electric motor 51 are used.
6, it can be easily attached to the existing pilot valve 16. That is, even if the control circuit 18 is installed in a place separated from the pressure setting unit 17 as in the related art, the control circuit 18 is replaced by replacing the unit of the pressure setting unit 17 with the pressure setting unit 17.
Can be changed to the configuration of the present invention built in the.

The auxiliary battery 57 is a backup power supply for supplying power to the control circuit 18 and the electric motor 51 at the time of a power failure. Therefore, pressure control can be performed continuously even during a power failure. The control circuit 18 includes a CPU 77 that calculates a control amount of the pressure setting unit 17 as described later.
And a memory 78 in which a set pressure control pattern of the secondary pressure P ₂ by the pressure control valve 14 is stored. Also, CP
U77 controls the driving of the electric motor 51 as the secondary pressure P ₂ is the pressure corresponding to the set pressure control pattern on the basis of the set pressure control pattern stored in the memory 78.

The control circuit 18 is connected to a connector 75 connected to an external device or a power supply. In the present embodiment, the connector 75 is provided with terminals H and G for AC 100 V, a terminal E for grounding, a terminal for alarm output, and terminals for communication. In the memory 78,
Based on the signal adjusting the spring force of the pressure setting spring 36 so as to maintain the set pressure value P _s corresponding to the gas consumption change daily as shown in the control program and FIG. 5 calculates the control amount of the pressure setting section 17 A data table of control data in which the rotational position of the rotating shaft 53 is determined for each time zone is stored.

FIG. 5 is a graph showing an example of the valve opening of the pressure control valve 14 corresponding to each time. As shown in FIG.
The set valve opening signal is calculated by the pressure rise control program or the pressure drop control program based on a valve opening corresponding to a predetermined set pressure value set for each time. Further, since the predetermined value P is set to a different value depending on conditions such as the pipe diameter and the characteristics of the pressure control valve 14, a value calculated in advance based on data obtained by experiments is set as a threshold value. .

FIG. 6 is an enlarged longitudinal sectional view showing the structure of the transmission mechanism such as the reduction gear 52, the rotating shaft 53, the coupling 54, and the adjusting screw 55. As shown in FIG. 6, a drive shaft 59 of the electric motor 51 has a drive gear 60 fitted and fixed at an end thereof, and the drive gear 60 has a large-diameter gear 61 fitted and fixed to the rotation shaft 53. Are engaged. The large-diameter gear 61
The small-diameter gear 62 fitted to the rotating shaft 53 below the large-diameter gear 6 fitted and fixed to the shaft 63 of the potentiometer 56
4 is slidably engaged. Therefore, the electric motor 5
The rotation amount of the rotating shaft 53 driven by 1 is also transmitted to the potentiometer 56 and detected as a voltage value associated with a change in the resistance value according to the rotation amount.

The large-diameter gear 61 is fitted slidably in the axial direction along the rotating shaft 53,
5 is urged to the position where it meshes with the drive gear 60 by the spring force of No. 5. The upper end of the clutch spring 65 is in contact with a spring receiver 66 that rotatably contacts the inner wall of the upper case 48 of the explosion-proof case 46. The upper end of the rotating shaft 53 protruding above the explosion-proof case 46 is connected by a connecting pin 67 fitted with a coupling 54 and inserted in a direction perpendicular to the axial direction. Further, the coupling 54
The lower end portion of the adjusting screw 55 is inserted into the upper end of the lock member 55, and an engagement groove 69 is formed to extend in the axial direction. The connecting pin 68, which is inserted laterally into the lower end of the adjusting screw 55, is slidably fitted in the engaging groove 69.

For this reason, the coupling 54 is
9 can be moved in the axial direction while the engagement between the connector pin 9 and the connecting pin 68 is maintained. On the outer periphery of the coupling 54, a handle 70 for manual operation protruding in the lateral direction is provided. Therefore, the rotating shaft 5 driven by the electric motor 51
3 is rotated by the coupling 54 and the connecting pins 67, 68.
Is transmitted to the adjusting screw 55 via the The adjusting screw 55 is inserted into the housing 31 of the pilot valve 16 described above, and is screwed into the central hole 37 a of the disc-shaped spring receiver 37 of the pressure setting spring 36. Also,
Since the rotation of the spring receiver 37 in the circumferential direction is restricted by the stopper 71, the spring receiver 37 moves up and down in the axial direction according to the rotation direction of the adjusting screw 55, and moves in the axial direction by an amount corresponding to the rotation angle. Therefore, the adjusting screw 55 is
By being driven and rotated by 1, the axial position of the spring receiver 37 is adjusted. As a result, the spring force is adjusted to any value by the compression length of the pressure setting spring 36 is changed to set the set pressure value P _s.

FIG. 7 is a view showing an operation method when adjusting the spring force of the pressure setting spring 36 by manual operation. FIG.
When adjusting the spring force of the pressure setting spring 36 by manual operation as shown in FIG.
Pull up. Accordingly, the rotating shaft 53 connected via the coupling 54 and the connecting pin 67 moves upward, and the large-diameter gear 61 and the small-diameter gear 62 fitted and fixed to the rotating shaft 53 also move in the same direction. Thereby, the large-diameter gear 6
1 is free from the drive gear 60 driven by the electric motor 51, and the small-diameter gear 62 extends in the axial direction, so that the large-diameter gear 64 fitted and fixed to the shaft 63 of the potentiometer 56. Is engaged.

The engagement groove 69 of the coupling 54 is
It moves upward while engaging with the connecting pin 68 provided at the lower end of the adjusting screw 55. When the manual operation handle 70 is rotated in this state, the adjustment screw 55 screwed into the spring receiver 37 is rotated around the axis, and the axial position of the spring receiver 37 is adjusted. Therefore, the compression length of the pressure setting spring 36 changes, and the spring force is adjusted to an arbitrary value.

When adjusting the spring force of the pressure setting spring 36 by manual operation, the amount of rotation of the rotary shaft 53 is transmitted to the potentiometer 56 and a voltage value corresponding to the compression length of the pressure setting spring 36 is measured. . Further, in the above embodiment, the case where the gas is provided on the line to which city gas is supplied is described as an example. However, the present invention is not limited to this, and the present invention is also applicable to pressure control of a pipe for supplying other gas or liquid. Of course you can.

[0035]

As described above, according to the first aspect of the present invention, the drive unit and the control unit are housed in one case, so that the drive unit and the control unit can be compactly constructed. The wiring work of the signal cable for electrically connecting the control unit and the control unit is not necessary or simple, and the time required for the installation work can be shortened by saving the labor of the installation work. Further, unlike a pressure control device having a mainspring type pressure setting device, an operator does not need to periodically wind the mainspring, thereby simplifying maintenance work after installation. Further, it is also advantageous when the control unit is replaced by using the already installed pressure control valve as it is.

According to the second aspect of the present invention, since the pressure adjustment section and the case in which the drive section and the control section are housed are detachable, the pressure setting section and the control circuit housed in the case are provided. Can be handled as one unit, so that the mounting operation and the disassembling operation can be easily performed, and the maintenance operation can be easily performed. In particular, when the control unit of the already installed pressure control valve is replaced, the pressure adjustment unit, the drive unit, and the control unit can be replaced collectively, so that the existing device can be easily improved.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an embodiment of a pressure control device according to the present invention.

FIG. 2 is an enlarged longitudinal sectional view showing an internal configuration of the pressure setting device 10.

3 is a side view of the pressure setting device 10. FIG.

4 is a block diagram of each electronic device housed in an explosion-proof case 46. FIG.

FIG. 5 shows a set pressure value P _s according to a change in gas usage per day.
FIG. 7 is a diagram showing control data in which the valve opening degree of the pressure control valve is determined for each time period so as to maintain.

FIG. 6 shows a reduction gear 52, a rotating shaft 53, a coupling 54,
It is a longitudinal cross-sectional view which expands and shows the structure of the transmission mechanism, such as an adjustment screw.

FIG. 7 is a diagram showing an operation method when adjusting the spring force of the pressure setting spring 36 by manual operation.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Pressure setting device 11, 81 Pressure control device 12 Upstream line 13 Downstream line 14 Pressure control valve 15 Actuator part 16 Pilot valve 17 Pressure setting part 18 Control circuit 19 Diaphragm 20 Upper diaphragm chamber 21 Lower diaphragm chamber 22 Pressure Setting spring 23 Primary pressure introducing line 24 Secondary pressure introducing line 25 Pilot pressure introducing line 26 Secondary pressure introducing line 31 Housing 32 Upper diaphragm 33 Lower diaphragm 36 Pressure setting spring 40 Nozzle 43 Valve part 45 Valve body 46 Explosion-proof case 48 Upper case 49 Lower case 51 Electric motor 52 Reduction gear 53 Rotating shaft 54 Coupling 55 Adjustment screw 56 Potentiometer 57 Auxiliary battery 71 Stopper 77 CPU 78 Memory

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Yasuhiro Nakamura 4-1-2, Hirano-cho, Chuo-ku, Osaka City, Osaka Prefecture Inside Osaka Gas Co., Ltd. (72) Inventor Kazuhiro Yonezawa 13 Tanyo, Kakegawa-shi, Shizuoka Prefecture Tokiko Shizuoka Co., Ltd. Inside the plant (72) Inventor Shizuo Kaneko 13 Tanyo, Kakegawa-shi, Shizuoka Tokiko Co., Ltd. Inside Shizuoka Plant (72) Inventor Yasuo Ozawa 13 Tanyo, Kakegawa-shi, Shizuoka Tokiko Corporation Inside the Shizuoka plant F-term (reference) 5H316 AA11 BB01 DD13 DD18 EE02 EE10 EE12 FF37 GG03 HH15 JJ04 JJ13

Claims (2)

[Claims] 1. A pressure control valve, which is provided in the middle of a pipe through which a fluid flows and controls a downstream pressure to a predetermined set pressure, and a pressure setting unit that controls a set pressure of the pressure control valve to a predetermined pressure. In the pressure control device, a set pressure of the pressure control valve is changed by increasing and decreasing a spring load of a pressure adjusting spring that adjusts a set pressure of the pressure control valve and a pressure setting spring provided in the pressure adjuster. A drive unit, and a control unit that controls the drive unit to set a spring load of the pressure setting spring to a predetermined set pressure. The drive unit and the control unit are housed in one case. A pressure control device. 2. The pressure control device according to claim 1, wherein the pressure adjustment unit and a case in which the drive unit and the control unit are housed are detachable.