NL7908293A - LIQUID CIRCULATION SYSTEM. - Google Patents

Description

N.O. 28,471 1 * 1

Liquid circulation system.

The present invention relates to a liquid circulation system with pressure control.

In all fluid circulation systems, certain arrangements must be made to accommodate the expansion and contraction of the fluid "within the system. In particular," these means consist of a pressurized accumulator tank which is so connected to the system that as the fluid expands, some of the fluid goes to the accumulator tank to prevent unwanted pressure build-up within the system. The accumulator-10 tank also supplies a small amount of liquid to the system as the liquid in the system cools, to prevent air from entering the system and to provide a more consistent heat transfer. In the past, in such systems, the accumulator tank was required to be pressurized because the liquid in the system itself is also pressurized. The need for a pressure vessel increases the cost and complexity of such fluid circulation systems and increases the need for maintenance because it is necessary to inspect the pressure vessel and its components.

The use of a venturi construction in a water circulation system is known from, for example, US patent 2,265,108. This patent uses the venturi construction, which is interposed between a storage tank, a heating device and an incoming water supply, such that the effective of the incoming water supply, passing through the venturi, forms an area of low pressure at the throat of the venturi, which serves to stimulate the circulation of the water from the storage tank.

Thus, this US patent uses the venturi construction as a jet pumping device to assist circulation of the water within the fluid system.

The use of an ejector, or jet pump construction, to circulate or assist water through a system in such circulation is well known from, for example, U.S. Patent Nos. 566,904, 1,418,583, 2,404.H4, 2,843,142, 35, 274,065, and 3 * 730,646. However, none of these patents disclose that the venturi construction can be positioned between an open storage tank and a fluid system such that the 7908293 *. 2 means which, for the purpose of liquid circulation, transport part of the liquid through the venturi to control the addition or discharge of liquid between the pressurized system and the atmosphere-communicating storage tank.

It is also known to use an atmospheric water storage tank in a liquid circulation system, such as shown in U.S. Pat. No. 3,554,441

The storage vessel is connected to the liquid circulation system in such a way that water can flow in and out of the system, depending on the relative difference between the system pressure and the pressure in the vessel. Overflowing of this vessel is prevented by connecting the vessel to a second storage vessel arranged at a lower level.

The present invention relates to a device 15 for controlling the supply or discharge of a liquid between a storage tank, which is in open communication with the atmosphere, and a liquid circulation system in a closed circuit. The means to achieve this consists of a venturi connected to the system such that its inlet communicates with the outlet of a pump, while the venturi outlet communicates with the inlet of the pump. The venturi's throat is connected to the storage tank and is normally under the same pressure as the storage tank (plus any hydrostatic pressure due to height difference) so that no flow occurs between the tank and the system. A small amount of fluid from the pump outlet circulates through the venturi and flows back to the pump inlet.

The amount of liquid circulating through the venturi is relatively small and does not affect the proper functioning of the rest of the liquid circulation system.

The pressure difference between the fluid at the venturi inlet and the venturi throat is fixed by the construction of the venturi.

Thus, if the pressure in the system and thus the pressure at the venturi inlet increases, the pressure at the venturi throat will also increase to maintain a constant differential pressure. When the pressure in the venturi throat rises above atmospheric pressure, some of the liquid from the system will pass through the venturi throat to the storage tank, which is in open communication with the atmosphere. Conversely, if the fluid pressure in the system were to drop, the pressure in the venturi throat also drops below the ambient atmospheric pressure, forcing fluid to flow from the 7908293 3 i storage tank to the venturi throat and then to the venturi throat. fluid system.

It is thus understood that the venturi control device according to the invention provides a simple and reliable means of automatically controlling the flow of liquid between a storage tank and a liquid circulation system based on the pressure within the system.

The present invention aims to provide a pressurized liquid circulation system that does not require a pressurized accumulator tank.

Another object of the invention is to provide means for automatically supplying or discharging liquid to or from a liquid flow system.

Another object of the invention is to provide a venturi construction in order to control the supply or discharge of liquid from the liquid flow system.

A further object of the invention is to provide means for supplying or discharging liquid to or from a liquid flow system, whereby no separate control valve is required for filling, so that the problems of such a valve construction are avoided.

The invention will now be described in more detail with reference to the drawing, in which;

Owner. 1 is the schematic of a liquid circulating system comprising the venturi controller according to the invention; Figure 2 is a graph of the pressure at various points along the longitudinal axis of the venturi of Figure 1; Figure 3 is a cross section of the venturi of Figure 1; and FIG. 4 is a partial sectional view of a pump housing incorporating the venturi construction of claim 3

The liquid flow control system according to the invention is shown schematically in Fig. 1 and consists of a pump or other circulating means 10, the inlet of which is connected to the return pipe 12 and the outlet of which communicates with the outlet pipe 14 To illustrate the invention, it is believed that the liquid flow system is a hydronic heating system that uses water as a circulating medium. It will be understood that this assumption is by way of example only and that the control device according to the invention can also be used in other closed loop liquid circulation systems.

The outlet pipe 14 brings the water from the pump 10 to a boiler 16, in which the water is heated and then the water is fed to the rest of the system (not shown) via the pipe 5 18. The rest of the system (not shown) ), can consist of a series of heating radiators, which transfer heat from the liquid to an enclosed space. After dissipating the heat, the water returns to the pump through the return pipe 12.

The venturi 20 with the inlet 20a, the throat 20b and the outlet 10 20c is connected to the circulation system through channels 22 and 24 such that a small portion of the water passing through the pump outlet moves to the inlet 20a, while the liquid exiting from the outlet 20c returns to the pump through the line 24 · The throat 20b is connected through the channel 28 to the water storage tank 15. Since the water storage tank 26 is in open communication with the atmosphere, the pressure at the ventricle is also the atmospheric pressure, so that under normal working conditions, there is no fluid transfer between the tank and the circulation system. '

The construction of the venturi is such that there is a constant pressure difference between the fluid pressure at the inlet 20a and the fluid pressure at the throat 20b.

The pressures at the inlet, throat and outlet, indicated by P1, P2 and P3 respectively, are shown schematically in Figure 2.

The difference between pressures P1 and P3 is due to the frictional losses as the liquid moves through the venturi.

The pressure difference between the pressure P1 and the pressure P2 appears to be constant, so when the pressure in the circulation system (P1) either increases or decreases, the pressure (P2) in the venturi will correspondingly increase or decrease. Thus, as the pressure in the liquid flow system 30 increases, due to increasing temperature or other factors, the pressure in the venturi section 20b will correspondingly increase. This increase in pressure P2 creates a pressure difference between the venturi section 20b and the storage tank 26, which remains at atmospheric pressure. This differential pressure causes water to flow from the system 35 to the storage tank 26 through the line 28. This provides the required dilation of the fluid flow system to prevent pressure from building up which would cause malfunction and, in the most extreme case, rupture of the fluid flow system. fluid flow system.

A similar effect occurs when the pressure in 40 decreases the fluid flow system (P1), since the corresponding decrease in pressure (P2) in the ventricle causes the pressure in the ventricle to drop below normal atmospheric pressure, creating a pre-pressure in favor of the storage tank 26. Water moves from the tank to the system through line 28, venturi 20 and line 24 ·

This ensures the automatic supply of water to the system to prevent damage or malfunction.

The venturi is shown in detail in Fig. 3 and consists of a housing 30 with a filter 20 attached to the inlet end.

Within the housing 30 there is a mouthpiece 34 and a diffuser 36, the area between the mouthpiece 34 and the diffuser 36 forming the throat portion 20b of the venturi. The throat portion 20b communicates with the conduit 28 through a number of openings 38 in the housing 30. The housing 30 also has two outlet ports 40, which communicate through the conduit 24 through the fluid system to allow fluid to flow back to the pump inlet.

A valve mechanism generally indicated at 42 is located adjacent the outlet end of the venturi to control the amount of fluid flowing through the venturi. The valve mechanism 20 also has two ports 43 »which, when aligned with the two outlet ports 40 in the housing 30, allow maximum flow through the system. A change in the placement of the two sets of ports by means of the screwdriver slot 44 in the valve mechanism 42 allows the flow through the venti to be adjusted and, as a result, the pressure in the system can be controlled.

The filter 32, the nozzle 34j, the diffuser 36 and the valve 42 are held in place by a curved snap ring 45 · Sealing means in the form of rubber O-rings 46 are located on the valve 42.

The venturi of Figure 3 can be externally attached to the system through separate lines 22 and 24, as shown in the schematic of Figure 1, or the venturi may be contained within the pump housing, as shown in Figure 4 · In this case the pump-55 housing 47 is configured to have a passage 48 therein, communicating at one end to the pump outlet passage 49 and communicating at or near the opposite end to the pump inlet 50. The housing 30 the elements shown above in fig. 3 is arranged in this passage in 4Q the orientation of fig. 4 · This installation provides a 7908293 6 * * packed construction for pump and control device without the need for external pipes and connections to fit. Although a particular orientation of the venturi is shown in Fig. 4, it will be understood that any orientation falls within the scope of the invention which is practical and allows the venturi inlet to communicate with the pump outlet and the venturi outlet communicates with the pump inlet.

The above description is for example only and does not limit the invention.

7908295

Claims (7)

1. Liquid circulation system in a closed circuit, with a pump or the like to circulate liquid through the system, which pump is provided with an inlet and an outlet and with a storage tank to store the liquid at atmospheric pressure, 5 with the characterized in that a venturi housing is connected to the liquid circulation system and to the storage tank to control the flow of the liquid between the storage tank and the system such that when the liquid pressure in the system drops below a certain value, liquid from the storage tank via the venturi tube flows to the system and when the liquid in the system rises above a certain value, liquid flows from the system through the venturi tube to the storage tank. 2. Liquid circulation system according to claim 1, characterized in that part of the liquid moves from the pump outlet through the venturi tube and is returned to the system upstream of the pump inlet. Liquid circulation system according to claim 2, characterized in that the venturi tube is arranged in the pump housing. 20 Liquid circulation system according to claim 3, characterized in that the venturi tube is arranged in a passage which is integral with the pump housing. Liquid circulation system according to claim 2, characterized in that valve means are provided to control the amount of liquid flowing through the vent tube. 6. Liquid circulation system according to claim 5, characterized in that the valve means in the housing of the venturi tube. Liquid circulation system according to claim 2, 3> 4, 5 or 6, characterized in that the storage tank is connected to the venturi tube at the venturi section. 7908293