Valve d'équilibrage, rapport de pilotage 1/1 - évent atmosphérique
Les valves d'équilibrage avec évent atmosphérique, assistées par pilotage, sont destinées à contrôler une charge entrainante. Le clapet laisse passer librement le débit depuis le distributeur (chambre 2) vers la charge (chambre 1) alors qu’un limiteur à action directe assisté par un pilotage contrôle le débit de la chambre 1 vers la 2. L’assistance par le pilotage à l’orifice 3 abaisse le tarage effectif du limiteur de pression à une valeur déterminée par le rapport de pilotage. la contre pression sur la chambre 2 n’affecte pas le tarage de la soupape car la chambre du ressort est référencée à la pression atmosphérique. Les autres dénominations pour cette valve comprennent entre autres, valve de contrôle de mouvement, et valve de freinage.
- Le tarage de la valve d’équilibrage doit être au moins égal à 1,3 fois la pression maximale induite par la charge.
- Tourner la vis de réglage dans le sens horaire pour réduire le tarage et libérer la charge.
- Lorsque la vis de réglage atteint la butée en sens horaire, la valeur de tarage est 14 bar (200 psi).
- Environ 1 goutte (0,07cm3) passe de la chambre de pilotage vers l’évent atmosphérique tous les 4000 cycles.
- La pression de fermeture est supérieure à 85% de la valeur de tarage lorsque la valve est à son tarage standard. Une valeur de tarage plus basse peut entraîner un pourcentage de la pression de fermeture plus faible.
- Les cartouches d’équilibrage SUN peuvent être installées directement dans une cavité usinée dans le corps d’un récepteur pour obtenir une protection supplémentaire et augmenter la raideur dans le circuit.
- Cette valve possède des joints d’étanchéité entre tous les orifices.
- Les valves équipées d’évents atmosphérique ou de drain indépendant peuvent nécessiter un rapport de pilotage plus bas que les valves standard pour assurer la stabilité de la machine.
- Les valves à 3 orifices équipées d’évent atmosphérique sont destinées à résoudre les problèmes sur les circuits existants équipés de valves non drainées. Avec le temps, ces valves peuvent donner lieu à des fuites externes ou laisser entrer l’humidité dans la chambre du ressort. Les valves d’équilibrage drainées à 4 orifices sont recommandées pour toutes nouvelles applications.
- Toutes les cartouches de maintien de charge à 3 orifices (valves d’équilibrage et clapets pilotés à l’ouverture), sont physiquement et fonctionnellement interchangeables (c’est-à-dire le même sens de débit, la même cavité pour une taille donnée).
- Cette valve intègre le concept Sun de la cartouche à visser "flottante" qui permet de minimiser les contraintes internes dues à un couple de serrage excessif de la cartouche et/ou à des écarts d’usinages des cavités ou des cartouches.
Cavité | T-17A |
Taille | 3 |
Capacité | 60 gpm240 L/min. |
Rapport de pilotage | 1/11/1 |
Pression Maximale Induite par la Charge Recommandée au Tarage Maximal | 3075 psi215 bar |
Réglage Maximum | 4000 psi280 bar |
Tarage en usine établi à | 2 in³/min.30 cc/min. |
Fuite Maximale à la Fermeture | 5 drops/min.0,3 cc/min. |
Pression d'ouverture du clapet de by-pass | 25 psi1,7 bar |
Adjustment - No. of CCW Turns from Min. to Max. Setting | 55 |
Operating Characteristic | standardstandard |
Fermeture | >85% of setting>85% of setting |
Dimensions du six pans de la valve | 1"1/4 in.31,8 mm |
Couple de serrage de la valve | 150 à 160 lbf ft203 - 217 Nm |
Taille du 6 Pans Creux de la Vis de Réglage | 5/32 in.4 mm |
Dimension du contre-écrou sur plat | 9/16" in.15 mm |
Couple de serrage du contre écrou | 80 - 90 lbf in.9 - 10 Nm |
Poids du composant | 1,60 lb0,70 kg |
Seal kit - Cartridge | Buna: 990117007 |
Seal kit - Cartridge | Polyurethane: 990117002 |
Seal kit - Cartridge | Viton: 990117006 |
Vented counterbalance valves should be used if you have backpressure in port 2 (inlet). Typical applications are regeneration circuits, master-slave circuits and servo/proportional valve circuits.
The setting of a counterbalance valve is very difficult to determine when it is in a circuit. This is due to cross-piloting, load-induced pressure, and cylinder ratio. The best way to check the setting is to remove the valve from the circuit. Before removing any valve, ensure machines and loads are mechanically held in position and that the valve is not under pressure at the time of its removal. Screw the valve into a simple, single cavity, line mounted body. Port 1 should be connected to a pressure source and ports 2 & 3 should be open. Increase the pressure on port 1 until the valve just starts to open. Repeat several times to ensure consistency.
The 5 drops/min. are at the point of reseat which is 85% of cracking pressure. If the valve is set correctly it will never see a load that is higher than 77% of cracking (1/1.3). At this pressure in a typical system the counterbalance can be considered a zero leak device. Using counterbalance valves to prevent drift is an accepted and common practice on almost all manlifts and hydraulically operated cranes. If a load drifts because of the counterbalance valve, the seat has probably been damaged and the valve should be replaced.
While cylinder drifting is often attributed to a leaking or damaged counterbalance valve, it can also be caused by cylinder seal leakage or changes in oil temperature. If you believe the seat of the counterbalance valve has been damaged, which can be caused by shock or contamination, it is advisable to replace the valve with a new factory set valve. Always follow the manufacturer's recommendations for servicing of hydraulically actuated machinery, and insure all loads are mechanically supported and cartridges are not under pressure when removed.
Il y a exactement 15 gouttes Sun dans un centimètre cube.
Yes it is sealed; however every time the valve is cycled a small amount of oil passes into the spring chamber--about 1 drop for every 4000 cycles. If the vent is blocked, the spring chamber will eventually fill with oil, building pressure until the valve won't open.
Counterbalance valves are pressure dependent devices, not flow dependent. They are designed to create pressure drop for their operation, so it is important not to oversize them. A higher pressure drop will generate greater system stiffness and help improve stability.
Two areas work to open a counterbalance valve, the relief area and the pilot area; the pilot area divided by the relief area equals the pilot ratio. Reverse flow from port 1 to port 2 is blocked by the check valve until a pilot pressure is sensed at port 3 (pilot) that is inversely proportional to the load pressure at port 1 (load). The pilot pressure at port 3 effectively reduces the relief valve setting. The setting is reduced according to the ratio of the differential pilot area on the piston compared to the differential relief area. For example, in a valve with a 3:1 pilot ratio, set for 3000 psi with a load of 2000 psi, the pilot pressure required to open the relief valve is 333 psi, i.e. (3000 psi - 2000 psi)/3 = 333 psi pilot pressure.
To calculate the pressure required to lower a load, use the following equations. These equations are under ideal conditions and do not consider any backpressure in the circuit or any effects of temperature on the oil.
Hysteresis is the difference between the pressure at which the valve will crack open and then reseat closed. Sun's counterbalance valve's hysteresis is typically less than 15%, which means the valve will have reseated to a closed position at 85% of its cracking or opening pressure.
It is always recommended that a counterbalance valve be set before it is installed in an application. Correctly setting a counterbalance when it is installed is very difficult due to the pilot assist and the interaction with the actuator. Once installed the adjust screw should be considered a manual override.
A closed loop transmission is meant to transfer the energy from dynamic braking to the prime mover. A counterbalance valve would put the energy in the form of heat into the small amount of oil contained in the loop. Backpressure caused by dynamic braking from the pump and charge pressure complicate matters. "Putting a vented counterbalance in a closed loop transmission is a crime; putting a non-vented valve in is a felony; putting a 10:1 valve in is a capital offence." Jeff Baker
First the valve is set to just crack open at the desired setting. The pressure is dropped to zero and then brought up to 85% of the setting. The valve is then piloted open and allowed to reseat. At this point the leakage rate must be less than 5 drops per minute. One detail that makes this test critical is extremely clean oil. If a valve leaks in an application, the seat has probably been damaged by contamination and the valve should be replaced. Before removing any valve, ensure machines and loads are mechanically held in position and that the valve is not under pressure at the time of its removal.
Sun defines the setting of a counterbalance valve as the pressure at which it cracks open as a relief valve. The flow rate at "crack" is the point where drops turn to a stream, about 1-2 cubic inches per minute. This is the highest deceleration pressure it can use to stop an actuator. The valve should be set at least 1.3 times the maximum expected load-induced pressure at port 1. In many cases the maximum load-induced pressure will be the same as the system relief setting.
Three-port vented, or atmospherically referenced, counterbalance valves are considered problem solvers for existing circuits that used a three port, non-vented valve. If a vented valve is required in a new design, four-port valves are recommended. Atmospherically referenced valves, over time, will leak externally or allow moisture into the spring chamber (resulting in corrosion) even though the spring chamber is sealed.
Generally, the 25 psi check spring is recommended for most applications as it is more robust and insensitive to rapid flow reversals. The 4 psi check cracking pressure should be used if there is a need to pull in make-up oil.
We do not recommend it. There is a possibility that the pilot area could get filled with oil and slow down or prevent the closing of the valve. A correct solution is to connect port 3, the pilot port, to port 2, the outlet port.
Backpressure at port 2 (inlet) may adversely effect the operation of a three port counterbalance valve as it directly opposes pilot pressure. When backpressure exceeds pilot pressure, it adds to the setting of the valve at a rate of 1 plus the pilot ratio times the backpressure, i.e. with 200 psi (14bar) back pressure at port 2 on a 3:1 counterbalance valve, the setting would increase by 800 psi (55 bar). In effect, backpressure drives the counterbalance valve closed. Using vented counterbalance valves typically will correct this problem.
The vast majority of counterbalance applications are satisfied with a 3:1 pilot ratio. Lower pilot ratios will increase system stability and higher ratios will be more efficient. 10:1 pilot ratio valves generally should be avoided.
There are 2 styles of load-reactive counterbalance cartridge valves. The first was designed by Racine and has the pilot in port 1 or the nose of the cartridge. The second style that Sun adapted was conceived by Fluid Controls, and has the load port (port 1) at the nose and the pilot coming in port 3. Sun co-founder John Allen said that a counterbalance was a valve designed around a spring. For a given size of cartridge you design a spring that has the most force and rate that can be wound, and then design the rest of the valve. The spring force dictates the relief area needed to achieve a setting.
The Racine design has 2 diameters. There is a pilot diameter and a larger diameter that creates the annular relief area. In order to maintain capacity the larger diameter has to be as large as possible. In order to increase pressure settings the annular relief area needs to be reduced. Because the big diameter is fixed and the differential annular area is being reduced, the result is the pilot diameter increases; hence the high pilot ratios.
Sun's (Fluid Control's) design has 3 diameters, the small one and the middle one defining the relief area and the middle one and the large one defining the pilot area. This design gives us the freedom to create pilot ratios that fit the application.
No. The counterbalance will be less violent than the check valve but the flow dynamics create backpressure spikes that can damage the valve. The circuit needs to be designed to dissipate the energy in a controlled fashion.
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