Description
Vacuum Breaker
Process Connection Size
1/2"
Body Material
Polypro
Seal Material
EPDM
Connection Type
Socket
Max Pressure at 40 - 75 Degrees F
100
Max Inlet Pressure (Bar)
10.3
Series VBM ½", ¾" & 1" Construction & Materials
Series VBM Vacuum Breakers are molded of Geon® type 1, grade 1, PVC(Polyvinyl Chloride), Corzan® CPVC, Glass-filled Polypropylene and Kynar® PVDF in pipe connection sizes ½", ¾" and 1".
A machined version, Series VB is available in PTFE in sizes ¾" and 1".
Diaphragms are of EPDM or FKM (Viton). Fasteners are not used on Series VBM. Fasteners used on PTFE Series VB are stainless steel and are NOT in contact with process liquid.
For alternate materials, please consult factory. Minimum quantities apply.
Threaded connections are standard on all models. Socket ends, BSP threads, JIS and DIN connections are available on all sizes and materials except PTFE VB. Inlet connection is shipped with standard dust cap. Cap is removable for applications where pipe connection is desired due to location, potential hazard, etc. The inlet connection is identical to the connection on the system side of the valve. If your application requires an unusual connection, custom material or configuration, please contact our Technical Team at 973-256-3000.
Connection Types:
Threaded connections are standard on all models. U.S. socket end connectors are available on all sizes and materials except PTFE VB. BSP, JIS, and metric DIN connections also available on VBM & VBS. Inlet connection is shipped with standard dust cap. Cap is removable for applications where pipe connection is desired due to location, potential hazard, etc. The inlet connection is identical to the connection on the system side of the valve. If your application requires an unusual connection, custom material or configuration, please contact our Technical Team at 973-256-3000.
Design:
The Plast-O-Matic Series VB and VBM Vacuum Breakers have only one moving part - the patented self-sealing diaphragm, and this provides both design simplicity and maximum operating dependability. This normally-closed design seals in the identical location every time producing a very dependable, long-life seal.Uses of Vacuum Breakers in a Typical Piping System
In the diagram above, a vacuum breaker is positioned on top of the supply tank to prevent implosion when the tank is drained. A second vacuum breaker is shown on a tee to prevent siphon in a vertical drop. This creates a pocket of air in the riser, lateral line, and drop to "break" the suction that would otherwise be created in the drop when the pump is turned off. The blue color indicates liquid in the system when the pump is turned off. When the system is re-started, an air release valve positioned along the high point of the pipeline is necessary to expel the air pocket for safe and efficient operation. Additional air release valves may be necessary at other points, depending upon the size and complexity of the pipeline. Placement of degassing valves (not shown) varies from system to system.
Performance:
These Vacuum Breakers will begin to break a vacuum at approximately 2 inches of mercury (1.0 PSI or 0,07 Bar negative pressure). Therefore the user must assure that the tank can withstand much more vacuum. This information must be obtained from the manufacturer of the tank. It is strongly advised to use a minimum 3X safety factor. The chart below shows air flow (SCFM) through the valve, vs. vacuum (inches of Hg) at the outlet of the valve, with atmospheric pressure at the inlet of the valve. These are calculated values, thus the need to apply a safety factor is important. The user of the valve must assure that the air flow through the valve will be enough to compensate for tank vacuum. Tank vacuum is a function of tank size, and rate at which liquid is flowing out of the tank.
Explanation of Graph:
- The above graphs relate liquid flow leaving an enclosed tank to the resulting vacuum created in the tank as air is entering the tank through the Vacuum Breakers.
- To use the graph, determine the rate of flow when draining the tank in SCFM and from that location on the vertical axis read across to the graph of the proper vacuum breaker size. At this intersection of the graph read down to the horizontal axis and determine the vacuum for the tank. This is the recommended vacuum rating of the tank which must be checked with the tank manufacturer's rating to be sure the tank is strong enough.
Anti-Siphon Applications:
For these applications the Vacuum Breakers must be installed in a "U-bend" at least 30 inches (2½ feet or 76 cm) above the highest liquid level. Depending on the safety factor desired for Anti-Siphoning this height would become 60 inches (5 feet or 152 cm) at 2 times safety factor which is recommended by Plast-O-Matic.
Use Caution in Dangerous Applications:
In the event a diaphragm failure could cause spraying of a dangerous liquid onto nearby equipment or personnel, or simply into the atmosphere where breathing the vapors would be dangerous, it is strongly advised to use a Plast-O-Matic Check Valve in lieu of the Vacuum Breaker, and pipe the vent or inlet side of the check valve to a safe remote location. The Check Valve will have the same flow capabilities of the Vacuum Breaker, and contains the same design.
Elimination of Vacuum in a System:
To prevent instrument or system malfunction, the same considerations are involved as in the tank application. The vacuum breaker should be installed at the highest location in the system. Plast-O-Matic Vacuum Breakers can be mounted in any position since they are self-sealing and do not rely on gravity to operate; however, upright is preferred. Also see Anti-Siphon section.
Pressure/Temperature Ratings:
Valve Body Material |
Valve Diaphragm Material |
Maximum Working Pressure (PSI) | ||||||
---|---|---|---|---|---|---|---|---|
75ºF | 110ºF | 140ºF | 180ºF | 220ºF | 240ºF | 284ºF | ||
(24ºC) | (43ºC) | (60ºC) | (82ºC) | (104ºC) | (115ºC) | (140ºC) | ||
PVC | EPDM Viton |
100 100 |
100 100 |
40 40 |
NR NR |
NR NR |
NR NR |
NR NR |
CPVC | EPDM Viton |
100 100 |
100 100 |
80 80 |
40 40 |
NR NR |
NR NR |
NR NR |
GPP | EPDM Viton |
100 100 |
100 100 |
100 100 |
80 80 |
NR NR |
NR NR | NR NR |
PVDF | EPDM Viton |
100 100 |
100 100 |
100 100 |
100 100 |
NR 60 |
NR 30 |
NR 10 |
Valve Body Material |
Valve Diaphragm Material |
Maximum Working Pressure (PSI) | ||||||
---|---|---|---|---|---|---|---|---|
75ºF | 110ºF | 140ºF | 180ºF | 220ºF | 240ºF | 284ºF | ||
(24ºC) | (43ºC) | (60ºC) | (82ºC) | (104ºC) | (115ºC) | (140ºC) | ||
PTFE | EPDM Viton |
100 100 |
90 90 |
80 80 |
70 70 |
NR 40 |
NR 20 |
NR 10 |