This disclosure relates generally to pneumatic actuator components, and more particularly, to apparatus to bias a moveable tube towards a seal.
Diaphragm actuators use pressurized air to actuate various process components. For example, pressurized air moves a diaphragm plate to actuate a process component such as a valve. Conveying pressurized fluid to the cavity above the diaphragm plate forces the diaphragm plate downward, thereby actuating the process component. Conversely, venting the cavity above the diaphragm or conveying high pressurized fluid to the cavity below the diaphragm reverses the actuation of the process component.
An example pneumatic actuator includes a diaphragm plate, a yoke housing, and a tube. The tube is to convey pressurized fluid between the yoke housing and the diaphragm plate, wherein the first end of the tube extends through a first seal gland in the diaphragm plate to form a seal against an outer surface of the tube and a second end of the tube extends through a second seal gland in the yoke housing to form a seal against the outer surface of the tube. The tube also includes the first end of the tube having a first cross-sectional area that is greater than a second cross-sectional area of the second end of the tube to bias the tube toward the yoke housing during operation of the pneumatic actuator.
An example pneumatic actuator includes a diaphragm plate, a yoke housing, a tube to convey pressurized fluid between the yoke housing and the diaphragm plate, and means for biasing the tube towards the yoke housing during operation of the pneumatic actuator.
Yet another example pneumatic actuator includes a tube to convey pressurized fluid between a yoke housing and a diaphragm plate having a first end and a second end opposite the first end, wherein the first end of the tube has a first cross-sectional area that is greater than a second cross-sectional area of the second end of the tube to bias the tube toward the yoke housing during operation of the pneumatic actuator.
The figures are not to scale. Wherever possible, the same reference numbers will be used throughout the drawing(s) and accompanying written description to refer to the same or like parts. As used in this patent, stating that any part (e.g., a layer, film, area, or plate) is in any way positioned on (e.g., positioned on, located on, disposed on, or formed on, etc.) another part, indicates that the referenced part is either in contact with the other part, or that the referenced part is above the other part with one or more intermediate part(s) located therebetween. Stating that any part is in contact with another part means that there is no intermediate part between the two parts.
Pneumatic actuators (e.g., diaphragm actuators, piston actuators, etc.) use pressurized fluid to actuate various process components, such as valves. For example, pressurized air conveyed to a diaphragm casing causes a diaphragm plate to actuate a process component. Conveying pressurized fluid to a cavity on a first side of the diaphragm can force the diaphragm plate in a first direction to actuate the process component. Conversely, venting the cavity on the first side of the diaphragm or conveying pressurized fluid to a cavity on a second side of the diaphragm reverses the actuation of the process component.
The diaphragm casing is typically connected to a yoke housing. The yoke housing contains an actuator stem and an actuator spring. For example, the actuator stem conveys the force applied to the diaphragm plate to the process component, such as a valve. The actuator stem is connected to the diaphragm plate and passes through the yoke housing. The actuator stem typically includes a stem connector to connect to the process component. Additionally, the actuator spring helps control the diaphragm plate and can return the diaphragm plate to an unactuated position. For example, the actuator spring is connected on one end to the yoke housing via a spring seat and on the other end to the diaphragm plate
Within the diaphragm casing, the diaphragm plate moves perpendicular to the upper and lower surfaces of the diaphragm plate to actuate the process component. However, the diaphragm plate may also be free to move laterally. As a result, components interacting with the diaphragm plate are designed to slide and pivot to accommodate the movements of the diaphragm plate. For example, a tube to convey pressurized fluid between the yoke housing and the diaphragm plate may be configured to pivot about a first seal gland in the diaphragm plate and a second seal gland on the yoke housing. In some known valves, the tube can become dislodged from the second seal gland. As a result, the tube can no longer convey pressurized fluid to the upper cavity.
In accordance with the present disclosure, the tube includes means for biasing the tube towards the second seal gland, thereby preventing the tube from dislodging from the second seal gland. In some examples, the means for biasing the tube towards the yoke housing include physical structures such as structural characteristics of the tube that produce a force differential between a first end and a second end of the tube. For example, the tube may have a greater surface area on a first end relative to a second end adjacent the yoke housing to create a force differential to bias the tube towards the yoke housing.
The diaphragm casing 102 is connected to an example yoke housing 112. The yoke housing 112 includes a stem 114 and a spring 116. For example, the stem 114 is connected to the diaphragm plate 106 and an actuator connector 118. In the illustrated example, the stem 114 is a rigid rod. However, in other examples, the stem 114 is another rigid structure. In some examples, the example spring 116 is positioned around the stem 114. However, in other examples, the spring 116 is positioned adjacent the stem 114. Additionally or alternatively, the spring 116 may be multiple springs.
Additionally, disposed in the yoke housing 112, is a pressurized fluid connection 120. For example, the pressurized fluid connection 120 may receive a pressurized fluid from a pressurized fluid source, a fluid pump, etc. In fluid communication with the pressurized fluid connection 120 is a tube 122 to convey pressurized fluid between the yoke housing 112 and the diaphragm plate 106. In the illustrated example, a first end 124 of the tube is fluidly coupled to the first cavity 108 and a second end 126 of the tube is fluidly coupled to the pressurized fluid connection 120.
The example tube 122 extends through a first seal gland 134 and the tube 122 is coupled to the first seal gland 134 via a first O-ring 136. In the illustrated example, the first seal gland 134 is disposed on the diaphragm 104 and the diaphragm plate 106, and is secured to the diaphragm plate 106 with a gland nut 138. Additionally, the example tube 122 extends through a second seal gland 140, and the tube 122 is coupled to the second seal gland 140 via a second O-ring 142. In the example of
The example tube 210 does not include means to bias the tube 210 towards the yoke housing 112 of
In the illustrated example, the first seal gland 220 includes a first passageway 230 that widens or flares from the first O-ring 222 toward opposing apertures 232, 234 of the first passageway 230. Similarly, the second seal gland 224 includes a second passageway 240 that widens or flares from the second O-ring 226 toward opposing apertures 242, 244. Thus, during operation of the pneumatic actuator 100 of
In accordance with the present disclosure, the first thickness 312 is greater than the second thickness 314 and, as a result, a first surface area 340 of a first end 342 of the tube 305 is greater than a second surface area 344 of a second end 346 of the tube 305. In the illustrated example of
In the illustrated example of
In the illustrated example, an outer surface 432 of the tube 405 couples with a first seal gland 440 via a first O-ring 442 to form a seal, and the outer surface 432 also couples with a second seal gland 444 via the second O-ring 446 to form a seal. As a result of the example tapered change 410, the first outer diameter 416 and the first inner diameter 420 are larger than the second outer diameter 418 and the second inner diameter 422 respectively. In some examples, the first thickness 412 is constant across the length of the tube 405, and the first thickness 412 is the same as the second thickness 414. In other examples, the first thickness 412 is different from the second thickness 414.
In accordance with the present disclosure, the tube 405 is biased towards the second seal gland 444 and the yoke housing 112 (
In the illustrated example of
From the foregoing, it will be appreciated that example apparatus and articles of manufacture have been disclosed that bias a pneumatic actuator tube to remain coupled to a first and second seal gland without adversely affecting the normal operation of the pneumatic actuator. Additionally, while the examples disclosed herein are described in connection with pneumatic actuators, the examples disclosed herein can likewise be implemented with any other device including a tube slidably and pivotably coupled to a first and second seal.
Although certain example methods, apparatus and articles of manufacture have been disclosed herein, the scope of coverage of this patent is not limited thereto. On the contrary, this patent covers all methods, apparatus and articles of manufacture fairly falling within the scope of the claims of this patent.