KR20130024298A - A pilot structure for a pneumatic positioner - Google Patents

Abstract

PURPOSE: A pilot structure for a pneumatic positioner is provided to reduce manufacturing costs and a failure frequency by having low structural complexity. CONSTITUTION: A pilot structure for a pneumatic positioner comprises a supply port(104), an output port(106), a discharge port(108), a signal port(102), a diaphragm(110), a first opening and closing member(112), and a second opening and closing member(114). The supply port supplies the constant pressure of fluid. The output port is connected to the supply port. The signal port is formed in one side of the structure. The diaphragm is biased toward the signal port by a first spring when there is no pressure signal from the signal port, and is biased to the opposite direction of the signal port when the pressure signal is inputted from the signal port. The first opening and closing member is biased toward the diaphragm by a second spring when the diaphragm is biased toward the signal port, and is biased to the opposite direction of the diaphragm when the diaphragm is biased to the opposite direction of the signal port. The second opening and closing member is integrated with the first opening and closing member and is interlocked with the movement of the first opening and closing member. The second opening and closing member blocks the fluid connection of the supply port and the output port when being biased toward the diaphragm with the first opening and closing member, and connects the supply port and the output port when being biased to the opposite direction of the diaphragm with the first opening and closing member.

Description

Pilot structure for pneumatic positioner {A PILOT STRUCTURE FOR A PNEUMATIC POSITIONER}

The present invention relates to a pilot structure for a pneumatic positioner, and more particularly, to provide a low complexity pilot structure that can be driven by one input signal.

In general, piping equipment for the transport of fluid is very important factors, such as temperature, pressure, and flow rate control of the fluid, which is made by a structural system installed in the required portion of the pipe. This structural system uses a pneumatic positioner that includes a pilot structure. The pilot structure used in the pneumatic positioner controls the actuator by outputting or interrupting the supplied constant pressure fluid to the actuator connected to the pilot structure.

One exemplary pilot structure is shown in FIG. The pilot structure consists of a supply port, an output port, an exhaust port, two signal inputs, two diaphragms, two opening and closing members integrated in each diaphragm, two springs for biasing each opening and closing member, and a supply port. And a first passage connecting the output port and a second passage connecting the output port and the discharge port. One of the two opening and closing members controls the opening and closing of the first passageway, and the other is for controlling the opening and closing of the second passageway.

This prior art pilot structure requires two separate signals, i.e., a signal for controlling the opening and closing of the connection from the supply port to the output port, and a signal for controlling the opening and closing of the connection from the output port to the discharge port, respectively. . Since two signals must be input at the same time to control the pilot structure, a slight timing error between the two signals may cause problems such as a malfunction of the pilot structure. In addition, there was a disadvantage that the complexity is high.

Accordingly, it is an object of the present invention to provide a pilot structure having low complexity and capable of driving with one input signal.

An improved pilot structure is provided as one aspect of the present invention. The pneumatic positioner pilot structure includes a supply port through which a constant pressure fluid is supplied; An output port in fluid communication with the supply port; Discharge port; A signal port formed on one side of the pilot structure; Formed adjacent to the signal port, biased towards the signal port by a first spring when there is no pressure signal from the signal port, and biased in the opposite direction to the signal port when a pressure signal is input from the signal port; Diaphragm being; The diaphragm disposed coaxially with the diaphragm, biased by a second spring towards the diaphragm when the diaphragm is biased in the direction of the signal port, and when the diaphragm is biased in the direction opposite the signal port A first opening / closing member in close contact with the diaphragm and biased in a direction opposite to the diaphragm; And fluid connection between the supply port and the output port when integrated with the first opening and closing member and operated in conjunction with movement of the first opening and closing member and biased in a diaphragm direction with the first opening and closing member. And a second opening / closing member configured to fluidly connect the supply port and the output port when shut off and biased together with the first opening / closing member in a direction opposite to the diaphragm. The first opening / closing member joins the diaphragm at one end of the passage and the other end of the passage is in fluid communication with the output port, and the diaphragm and the when the first opening member is biased toward the diaphragm. And a stopper for forming a spaced space between the first opening / closing members. When the first opening and closing member is biased in the diaphragm direction, through the space between the diaphragm and the first opening and closing member formed by the stopper and the passage of the first opening and closing member, the output port and the discharge port And fluidly connect the diaphragm and the passage of the first opening / closing member when the diaphragm is biased in a direction opposite to the diaphragm.

In another aspect of the present invention, a pilot valve having the pilot structure is provided.

The pilot structure for the pneumatic positioner of the present invention is driven by one input signal to provide simple and precise control. In addition, the present pilot structure can reduce manufacturing costs due to low structural complexity, and the frequency of failures is reduced.

1 is a diagram of one exemplary prior art pilot structure.
2 is a diagram of an exemplary pilot structure in accordance with one embodiment of the present invention.
3 is an illustration of an exemplary pilot structure and an actuator used with the pilot structure in accordance with one embodiment of the present invention, illustrating the open state of the pilot structure.
4 is a diagram of an exemplary pilot structure and an actuator used with the pilot structure, in accordance with one embodiment of the present invention, illustrating a stationary state of the pilot structure.
FIG. 5 is a diagram of an exemplary pilot structure and actuator used with the pilot structure in accordance with one embodiment of the present invention, illustrating the closed state of the pilot structure. FIG.

2 illustrates a pilot structure 100 for an exemplary pneumatic positioner in accordance with one embodiment of the present invention. As shown, the pilot structure 100 includes a signal port 102, a supply port 104, an output port 106, an exhaust port 108, a diaphragm 110, a first opening / closing member 112, and a first opening 112. 2 may include an opening and closing member 114. Signal port 102 receives a pressure signal. Supply port 104 supplies a constant pressure fluid. The output port 106 is connected to an actuator (not shown) to supply the actuator with a fluid of pressure provided from the supply port 104 when the pilot structure 100 is open. The discharge port 108 discharges fluid from the actuator when the pilot structure 100 is closed.

The diaphragm 110 is disposed adjacent to the signal port 102. The diaphragm 110 includes a spring that biases the diaphragm 110 in a direction toward the signal port 102. The diaphragm 110 is biased by this spring in the direction towards the signal port 102 when there is no pressure signal from the signal port 102 and the signal port 102 when a pressure signal is provided from the signal port 102. Biased in the opposite direction.

The first opening / closing member 112 is disposed adjacent to the diaphragm 110. The first opening and closing member 112 includes a spring for biasing the first opening and closing member 112 in the direction toward the diaphragm 110. The first opening / closing member 112 is in close contact with the diaphragm when the diaphragm 110 is biased in a direction opposite to the signal port 102 and is biased in the direction opposite to the signal port 102 in association with the movement of the diaphragm. In addition, the first opening and closing member 112 includes a fluid passage in the center. One end of the passage joins the diaphragm and the other end of the passage is in fluid connection with the output port 106. The first opening / closing member 112 includes a stopper for forming a space spaced between the diaphragm 110 and the first opening / closing member 112 when the first opening / closing member 112 is biased in the signal port direction. do. When the first opening / closing member 112 is biased in the direction of the signal port 102, the output port and the discharge port are fluidly connected through the space formed by the stopper and the passage of the first opening / closing member 112. When the first opening / closing member 112 is biased in the opposite direction to the signal port 102, the fluid connection between the output port and the discharge port is due to the joining of the passage of the diaphragm 110 and the first opening / closing member 112. Is blocked.

The second opening / closing member 114 is integrated with the first opening / closing member 112. Thus, the second opening and closing member operates in conjunction with the movement of the first opening and closing member 112. The second opening / closing member 114 is supplied with the supply port 104 and the output port 106 when the second opening / closing member 114 (and the first opening / closing member 112) is biased in the direction of the signal port 112. Shut off fluid connections. The second opening / closing member 114 is supplied with the supply port 104 and the output port 106 when the second opening / closing member 114 (and the first opening / closing member 112) is biased in a direction opposite to the signal port 112. ) To fluid connection.

3 is an illustration of an exemplary pilot structure and an actuator used with the pilot structure in accordance with one embodiment of the present invention, illustrating the open state of the pilot structure. In the open state, a pressure signal is input through the signal port 102 and the diaphragm 110 is biased in the opposite direction to the signal port 102. As the diaphragm 110 moves in the opposite direction to the signal port 102, the diaphragm 110 and the first opening and closing member 112 are joined together, and the first opening and closing member 112 is also biased in the direction opposite to the signal port 102. It is fresh. The passage of the opening and closing member 112 is blocked by the bonding of the diaphragm 110 and the first opening and closing member 112, and the output port 106 and the discharge port 108 are closed. At the same time, the second opening and closing member 112 integrated with the first opening and closing member 112 is also biased in the direction opposite to the signal port 102. At this time, the second opening and closing member 112 fluidly connects the supply port 104 and the output port 106. The constant pressure fluid supplied from the supply port 104 is provided to the actuator via the output port 106.

4 is a diagram of an exemplary pilot structure and an actuator used with the pilot structure, in accordance with one embodiment of the present invention, illustrating a stationary state of the pilot structure. In the stopped state, the signal port 102 inputs a predetermined pressure signal for stopping the pilot structure. This predetermined pressure is selected to be smaller than the force of the spring biasing the first opening and closing member and the force of the spring biasing the second opening and closing member. Due to this pressure, the diaphragm 110 is biased in the direction opposite to the signal port 102 so that the first opening / closing member 112 and the diaphragm 110 are joined, and the output port 106 and the discharge port 108 are closed. do. However, the first opening and closing member and the second opening and closing member are biased in the direction of the signal port 102 as it is, so that the output port and the supply port are also closed. Therefore, the discharge port, the output port and the supply port are all closed, the operation of the pilot structure is stopped, and the actuator is also stopped accordingly.

FIG. 5 is a diagram of an exemplary pilot structure and actuator used with the pilot structure in accordance with one embodiment of the present invention, illustrating the closed state of the pilot structure. FIG. In the closed state, the pressure signal through the signal port 102 is removed. The diaphragm 110, the first opening and closing member 112, and the second opening and closing member 114 are all biased in a direction toward the signal port 102. As described above, a space is formed between the diaphragm 110 and the first opening / closing member 112 by the stopper, thereby connecting the output port 106 and the discharge port 108. The supply port 104 and the output port 106 are closed by the second opening and closing member 114. Thus, pressure is released from the actuator through the discharge port 108.

While the invention has been described with respect to particular embodiments, it is for illustrative purposes only and does not limit the invention. The scope of the invention is to be determined only by the claims.

Pilot Structure 100 Signal Ports 102
Supply Port 104 Output Port 106
Outlet Port 108 Diaphragm (110)
First opening and closing member 112, Second opening and closing member 114

Claims (2)

As a pilot structure for the pneumatic positioner,
A supply port through which a fluid of constant pressure is supplied;
An output port in fluid communication with the supply port;
Discharge port;
A signal port formed on one side of the structure;
Formed adjacent to the signal port, biased towards the signal port by a first spring when there is no pressure signal from the signal port, and biased in the opposite direction to the signal port when a pressure signal is input from the signal port; Diaphragm being;
The diaphragm disposed coaxially with the diaphragm, biased by a second spring towards the diaphragm when the diaphragm is biased in the direction of the signal port, and when the diaphragm is biased in the direction opposite the signal port And a first opening / closing member in close contact with the diaphragm and biased in a direction opposite to the diaphragm.
When integrating with the first opening / closing member, operating in conjunction with movement of the first opening / closing member, and biased in a diaphragm direction with the first opening / closing member, shut off fluid connection between the supply port and the output port. A second opening and closing member configured to fluidly connect the supply port and the output port when biased together with the first opening and closing member to the diaphragm;
The first opening and closing member is
A passage in which one end of the passage joins the diaphragm and the other end of the passage is in fluid communication with the output port, and
A stopper for forming a space spaced between the diaphragm and the first opening and closing member when the first opening and closing member is biased toward the diaphragm,
When biased in the diaphragm direction, fluidly connects the output port and the discharge port through a space between the diaphragm formed by the stopper and the first opening / closing member and the passageway of the first opening / closing member, and
When biased in the opposite direction of the diaphragm, the pilot structure for the pneumatic positioner being configured to block fluid connection between the output port and the discharge port due to the joining of the passage of the diaphragm and the cylindrical opening / closing member. . Pilot valve having a pilot structure of claim 1.

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