ES2837973T3 - Siphon with check valve and vent valve - Google Patents

Abstract

Bottle siphon (10) for a drain, the bottle siphon comprising: a siphon body (12) defining a siphon inlet (14) and a siphon outlet (16), wherein the siphon body ( 12) comprises an upper part (28) and a lower part (30), the lower part being threadedly connected to the upper part (28) by means of a threaded connection (32) and including an insert (18), arranged in relation to the inlet (14) and outlet (16) so that the flow passing through the siphon (10) is defined by a sinuous flow path (20) between the inlet (14) and the outlet (16) so that In operation, there is a hydraulic seal (22) between the siphon inlet (14) and the siphon outlet (16), a non-return discharge pressure valve (24) located in a neck that connects the siphon outlet (16 ) to an upper part (28) of the siphon body (12), wherein the non-return discharge pressure valve (24) comprises a pressure valve inlet (34) and a a pressure valve outlet (36) and a pressure valve component (38), wherein the pressure valve inlet (34) and a pressure valve outlet (36) lie in different vertical planes and are connected by a flow path (40), in which the flow direction through the pressure valve inlet (34) and the flow direction through the pressure valve outlet (36) are parallel but separate ; wherein the pressure valve component (38) rests on a pressure valve component holder (42), and includes a gap on the pressure valve component (38), wherein the gap defines a pocket of air providing a barrier between the pressure valve outlet (36) and the pressure valve inlet (34); wherein a lower surface of the pressure valve component (44) forms a seal with an upper surface (46) of the pressure valve component holder (42), wherein the seal between the pressure valve component ( 38) and the pressure valve component bracket (44) is held, in the absence of a pressure differential, by gravity, pulling gravity on the pressure valve component (38) downward to engage with the pressure valve bracket pressure valve component (44); and wherein, in operation, in the presence of a negative pressure differential across the non-return discharge pressure valve (24), the non-return discharge pressure valve (24) is functional to open to allow it to pass air through the non-return discharge pressure valve, wherein the pressure valve component (38) is raised away from the pressure valve component bracket (42), to alleviate the pressure differential although in the presence of a positive pressure differential across the non-return discharge pressure valve (24), the non-return discharge pressure valve (24) is functional to close to prevent air from passing through the non-return discharge pressure valve (24) , wherein the pressure valve component (38) is pressed into engagement with the pressure valve component holder (42); characterized by that; A polymer diaphragm check flow valve (23) provided by a duckbill valve is located within the siphon body adjacent to the siphon inlet (14), in which the duckbill valve (23) is housed within the insert, in which the lower end of the duckbill valve (23) is submerged in the water that provides the hydraulic seal (22), in which the diaphragm non-return flow valve (23) allows A flow of fluid goes from the siphon inlet (14) to the siphon outlet (16) although it prevents flow from the siphon outlet (16) to the siphon inlet (14).

Description

DESCRIPTION

Siphon with check valve and vent valve

Field of the invention

This invention relates to a siphon for a drain.

Background of the invention

Water-seal siphons are widely used throughout the world in building plumbing installations. Generally, a water siphon is placed between the outlet of a sink, a sink, a bathtub, a shower, etc., and the drain pipe to prevent odors, rodents and other unwanted organisms or substances that may be present in the sewer pipe enters the building through the exit.

There are several different types of siphons and a well known and widely used siphon is the bottle siphon. Bottle siphons are particularly popular due to their compact nature.

However, bottle siphons have drawbacks. For example, when there are a large number of installations in the same plumbing system, there may be a negative pressure differential between the inlet side of the bottle siphon and the outlet side.

If this pressure differential is large enough, the water that forms the siphon can be sucked out, exposing the environment around the siphon inlet to the contents of the drain pipe.

This problem has been partially alleviated by the use of a non-return flow valve at the valve inlet, with the non-return flow valve providing a barrier between the siphon inlet and the siphon outlet in the event that the siphon seal is sucked in. Although this barrier has proven successful in preventing the entry of insects and the like, the non-return flow valve is known to allow the entry of odors.

US3707986 discloses a one-way diaphragm for use in combination with a sink drain, in which the diaphragm includes a plurality of axially extending radially oriented double thickness flanges which are corrugated substantially throughout their length. The lower end of each flange is divided so that the water draining from the sink can flow through. The diaphragm is made of elastic material so that the flanges are normally closed and provide a seal at its lower end to prevent the backflow of gases, fluids and foams into the sink.

Document EP 1059391 describes a valve to avoid a total or partial vacuum that sometimes occurs in sewage pipes. Typically, the valve is installed near the anti-siphon trap that accompanies the sewage pipes. This valve guarantees the hydraulic closing of the siphons, and prevents unpleasant odors from reaching the outside. Document EP 1059 391 A2 describes a bottle siphon according to the preamble of claim 1.

Brief description of the invention

According to the present invention, there is provided a bottle siphon for a drain, as mentioned in claim 1.

In at least one embodiment of the present invention, a siphon is provided which when connected to a sewage downspout allows air to enter through the siphon outlet to relieve a negative pressure differential across the non-return pressure valve, that is, when the pressure inside the sewage downspout is lower than the ambient pressure at the valve inlet. Generally, for a siphon, this ambient pressure will also be the pressure at the siphon inlet. Therefore, this arrangement ensures that the pressure differential does not reach a sufficient level to generate a sufficient force to suck the hydraulic seal out of the siphon and into the sewage downspout. However, in the case of a positive pressure differential of sufficient magnitude, the water seal is prevented from being pushed through the siphon inlet by the inlet check flow valve. For the avoidance of doubt, "negative pressure differential" in this context means a pressure differential that would apply a pulling force to the water seal in a siphon, which, in operation, is such that the water seal experiences a force that, if the differential pressure reaches a sufficient magnitude, it is strong enough to make the water seal flow through the siphon outlet.

Mounting the non-return discharge pressure valve on the outlet neck ensures that the non-return discharge pressure valve is positioned where the negative pressure differential that may exist between the inlet and the siphon outlet is the strongest.

The presence of an air pocket ensures that, if the water accumulated in the siphon enters through the pressure valve outlet, the presence of an air pocket in the hole prevents the water or waste accumulated in the bottle siphon from contaminating seal component and prevent the pressure valve component from closing properly.

Brief description of the drawings

Next, an embodiment of the present invention will be described with reference to the accompanying drawings in which:

Figure 1 is a side view of a bottle siphon for a drain according to an embodiment of the present invention;

Figure 2 is a sectional view of the bottle siphon of Figure 1 in a closed discharge pressure valve configuration;

Figure 3 is a sectional view on the line A-A shown in Figure 2;

Figure 4 is a section of the bottle siphon of Figure 1 shown in a discharge pressure valve open position;

Detailed description of the drawings

First, reference is made to Figure 1, a side view of a bottle siphon, generally indicated by reference numeral 10 for a drain (not shown), and to Figure 2, a section of the bottle siphon. Figure 1 shown in a closed position of a discharge pressure valve 24.

The bottle siphon 10 comprises a siphon body 12, which defines a siphon inlet 14 and a siphon outlet 16. The body further includes an insert 18 to create a sinuous flow path 20 between the siphon inlet 14 and the outlet. siphon 16, such that, in operation, there is a hydraulic seal 22 between the siphon inlet 14 and the siphon outlet 16. The bottle siphon 10 further comprises a non-return inlet flow valve 23 located next to the inlet of the siphon. siphon 14 and a non-return discharge pressure valve 24 located in a neck 26 that connects the valve outlet 16 to the upper body of the siphon 28.

The siphon body 12 comprises an upper part 28 and a lower part 30, the lower part being threadedly connected to the upper part 28 by a threaded connection 32.

The non-return inlet flow valve 23 comprises a polymer diaphragm valve adapted to allow fluid flow from the siphon inlet 14 to the siphon outlet 16.

The non-return discharge pressure valve 24 comprises a pressure valve inlet 34, a pressure valve outlet 36 and a pressure valve component 38. The pressure valve inlet 34 and the pressure valve outlet 36 are connected by a flow path 40. Pressure valve component 38 rests on pressure valve component holder 42, with a pressure valve component lower surface 44 forming a seal with an upper supporting surface 46.

In the absence of a pressure differential, the joint between the pressure valve component 38 and the pressure valve component bracket 44 is held by gravity, pulling gravity on the pressure valve component 38 downward to engage with pressure valve component bracket 44.

If there is a pressure differential across the pressure valve component 38, in case the pressure in the siphon 16 in the region indicated with "X" adjacent to the outlet of siphon 16 is less than in the external environment indicated with "Y", which is the ambient pressure present at siphon inlet 14 and pressure valve inlet 34, pressure valve component 38 will rise away from pressure valve component bracket 42, allowing air to flow through. through path 40. This is shown more clearly in Figure 4, a sectional view of the bottle siphon of Figure 1 shown in an open position of pressure valve 24.

If the pressure differential across the pressure valve component 38 is a positive pressure differential, that is, the pressure in the region "X" is greater than in the external environment "Y", then the pressure valve component 24 is pressed into engagement with the pressure valve component bracket 42. This prevents harmful vapors from escaping down the drain line (not shown) that will connect to the siphon outlet 16. The applied pressure in such a situation to push the hydraulic seal towards the inlet 14 it is resisted by the non-return inlet flow valve 23 which prevents the flow of fluid coming from the siphon body 12 from exiting through the siphon inlet 14.

The negative pressure differential relief prevents a pulling force from being applied to the water seal 22, preventing it from being sucked into the flow path 20 and down the drain line. This ensures that the hydraulic seal is maintained by preventing the entry of harmful vapors and the like from the drain pipe through the sinuous flow path 20 and out of the siphon inlet 14.

As can be seen in Figures 1, 2 and 4, the pressure valve inlet 24 and the pressure valve outlet 36 lie in different vertical planes. That is, the direction of flow through pressure valve inlet 34 and the direction of flow through pressure valve outlet 36 are parallel, yet separate.

This allows the inlet 34 and outlet 36 to be arranged in a more complex formation and for the inlet 34 to have a gravity actuated pressure valve component 38 but disposed above the siphon outlet 16. The pressure valve component arrangement 38 above the siphon outlet 16 reduces the possibility that the flow that is in the siphon 10 and exiting the siphon outlet 16 will contaminate the pressure valve component 38. This possibility is further reduced by the inclusion of a gap immediately above the pressure valve component 38. The gap provides a region in which air can become entrapped if a barrier is provided between the pressure valve outlet 36 and the pressure valve inlet 34, such that If the drain line becomes blocked and the siphon 10 fills with fluid, the fluid will not be able to displace the air within the pressure valve path and flow to the pressure valve component 38.

Various modifications and improvements can be made to the embodiments described above without departing from the scope of the invention, as defined in the appended claims.

Claims (1)

1. Bottle trap (10) for a drain, the bottle trap comprising: a siphon body (12) defining a siphon inlet (14) and a siphon outlet (16), wherein the siphon body (12) comprises an upper part (28) and a lower part (30), the lower part being threadedly connected to the upper part (28) by means of a threaded connection (32) and including an insert ( 18), arranged relative to the inlet (14) and outlet (16) so that the flow passing through the siphon (10) is defined by a sinuous flow path (20) between the inlet (14) and the outlet (16) so that, in operation, there is a hydraulic seal (22) between the siphon inlet (14) and the siphon outlet (16), a non-return discharge pressure valve (24) located in a neck that connects the siphon outlet (16) to an upper part (28) of the siphon body (12), wherein the non-return discharge pressure valve (24 ) comprises a pressure valve inlet (34) and a pressure valve outlet (36) and a pressure valve component (38), wherein the pressure valve inlet (34) and a pressure valve outlet pressure (36) lie in different vertical planes and are connected by a flow path (40), in which the direction of flow through the pressure valve inlet (34) and the direction of flow through the pressure valve outlet (36) are parallel but separate; wherein the pressure valve component (38) rests on a pressure valve component holder (42), and includes a gap on the pressure valve component (38), wherein the gap defines a pocket of air providing a barrier between the pressure valve outlet (36) and the pressure valve inlet (34); wherein a lower surface of the pressure valve component (44) forms a seal with an upper surface (46) of the pressure valve component holder (42), wherein the seal between the pressure valve component ( 38) and the pressure valve component bracket (44) is held, in the absence of a pressure differential, by gravity, pulling gravity on the pressure valve component (38) downward to engage with the pressure valve bracket pressure valve component (44); and wherein, in operation, in the presence of a negative pressure differential across the non-return discharge pressure valve (24), the non-return discharge pressure valve (24) is functional to open to allow it to pass air through the non-return discharge pressure valve, wherein the pressure valve component (38) is raised away from the pressure valve component bracket (42), to alleviate the pressure differential although in the presence of a positive pressure differential across the non-return discharge pressure valve (24), the non-return discharge pressure valve (24) is functional to close to prevent air from passing through the non-return discharge pressure valve (24) , wherein the pressure valve component (38) is pressed to engage the pressure valve component holder (42); characterized by that; A polymer diaphragm check flow valve (23) provided by a duckbill valve is located within the siphon body adjacent to the siphon inlet (14), in which the duckbill valve (23) is housed within the insert, in which the lower end of the duckbill valve (23) is submerged in the water that provides the hydraulic seal (22), in which the diaphragm non-return flow valve (23) allows A flow of fluid goes from the siphon inlet (14) to the siphon outlet (16) although it prevents flow from the siphon outlet (16) to the siphon inlet (14).