SU1096614A1 - Flow governor - Google Patents

Abstract

A FLOW CONTROLLER, comprising a housing divided by a membrane into flow and non-flowing chambers, communicated by channels with a cavity of an inlet channel located coaxially with the inlet of a channel communicated with a non-flowing chamber, a valve and a load element, which is designed to increase accuracy and simplify regulation It contains a damper associated with the actuator, mounted in front of the inlet opening of the channel communicated with the non-flowing chamber.

Description

The invention relates to automation, in particular to devices for controlling the flow rates of liquids (gases and gases), and can be used to control the flow rates of reagents in technological processes. A flow regulator is known that contains a housing divided by a membrane connected with a load element (load) flow and non-flowing chambers associated with the cavity of the inlet duct, a valve, as well as additional membranes and an adjustable choke l. The closest in technical essence to the invention is a flow controller containing a housing with a membrane on a flow-through and non-flow-through chambers communicated by channels with the cavity of the inlet duct located coaxially with the inlet of the duct connected to the stagnant chamber and a load element made in the form of a spring located in the flow-chamber 21. Disadvantages of known regulators are the complexity of their design and low accuracy, due to the possibility of kan clogging, fishing, with throttle elements associated with a leaky chamber, which: leads to a change in the magnitude of differential pressure And, consequently, to a deviation from a predetermined flow rate. The purpose of the invention is to simplify the design and improve the accuracy of the flow regulator. This goal is achieved by the fact that the flow regulator, containing a cone, divided by a membrane into flow and non-flowing chambers, communicated by channels with the cavity of the inlet channel,

A coaxially disposed inlet port of a channel in communication with the non-flowing chamber, a valve and a load element, contains a valve connected to the actuator mounted in front of the inlet ports of the channel in communication with the non-flowing camera.

Figure 1 shows the proposed flow controller; FIG. 2 is a sectional view of FIG. 1} in FIG. 3 — section BB in FIG.

The flow regulator consists of flow-through 1 and non-flowing 2 chambers separated by a membrane 3 with a load element (load) A. Camera 2 is connected by channel 5 to the input

entered with axis 9, indicates the magnitude of the flow to be stabilized. The force of rotation of the axis 9 with the valve 8 is insignificant and can be combined with any actuator.

Simplification of the structure is achieved by performing the task assembly in the form of a motorized gate installed in front of the entrance opening of the chamber in communication with the leak-free chamber. In addition, the use of a damper also ensures that the accuracy of the regulator works during operation on contaminated and crystallizing cells, since it is less sensitive to contamination by chamber 6 communicating with flow chamber 1 compared to a throttle. Input channel 7 is coaxially the inlet to the channel 5, and between them in the chamber 6 there is located a valve 8 connected to the drive, having an axis 9 of the gate with a arrow indicator 10. The chamber 1 has a valve 11 communicating with the output channel 12. The regulator consumption as follows. Liquid or gas enters through the channel 7 into the inlet chamber 6. If the damper 8 does not overlap the channel 5, then in the channel 5 and chamber 2 a sum of static and dynamic pressure is formed. From the inlet chamber 6, the controlled medium enters the chamber 1, where only static pressure acts, and through valve 11 to the outlet channel 12. Thus, the diaphragm 3 is acted upon by a dynamic pressure force directed towards the force of the weight of the load 4, and the value of the given flow through the regulator determines the equality of these forces. When the flow rate decreases, the dynamic pressure decreases, under the action of the load 4, the opening degree of the valve 11 increases, and the flow rate is restored to its previous value. As the flow rate increases, the dynamic pressure increases. The force of the dynamic pressure, overcoming the weight of the load 4, reduces the degree of opening of the valve 11. The flow rate of the medium decreases to the same value. If the valve 8 is turned on axis 9, then the inlet of channel 5 partially overlaps from the incoming medium jet, and thus the dynamic pressure in channel 5 and chamber 2 is reduced at the same flow rate. Consequently, the value of stabilized) the increased consumption increases. Pointer 10, St

Claims (1)

FLOW REGULATOR, comprising a housing, divided by a membrane • into flowing and non-flowing chambers, connected by channels with a cavity of the inlet channel, located coaxially with the inlet of the channel, in communication with the non-flowing chamber, a valve and a load element, characterized in that, in order to improve accuracy and simplify controller, it contains a damper associated with the actuator installed in front of the inlet of the channel in communication with the non-flow chamber. Fog. 1 I 1 1096614