GB2555670A - Dosing assembly - Google Patents

Abstract

A dosing assembly 100 for connection to a heating or cooling system is disclosed. It comprises a dosing vessel 102 comprising a chamber 104, and inlet and outlet ports 114, 110 communicating the chamber with higher and lower pressure parts of the system respectively. The chamber communicates with an upwardly facing opening which is closed with a removable lid 106. The assembly includes a basket 118 for retaining fluid treatment chemicals, the basket being inserted into or removed from the chamber via the opening. The permeable basket maintains the chemicals in the flow path from inlet to outlet, thereby allowing the chemicals to be exposed to the fluid flow and be dissolved and carried through the system. A bag-type filter may be located inside the basket. The vessel may comprise a bubble coalescing device, as well as pressure sensors to detect a pressure differential across the basket.

Description

(54) Title of the Invention: Dosing assembly

Abstract Title: Heating or cooling system dosing assembly comprising basket for solid chemicals (57) A dosing assembly 100 for connection to a heating or cooling system is disclosed. It comprises a dosing vessel 102 comprising a chamber 104, and inlet and outlet ports 114, 110 communicating the chamber with higher and lower pressure parts of the system respectively. The chamber communicates with an upwardly facing opening which is closed with a removable lid 106. The assembly includes a basket 118 for retaining fluid treatment chemicals, the basket being inserted into or removed from the chamber via the opening. The permeable basket maintains the chemicals in the flow path from inlet to outlet, thereby allowing the chemicals to be exposed to the fluid flow and be dissolved and carried through the system. A bag-type filter may be located inside the basket. The vessel may comprise a bubble coalescing device, as well as pressure sensors to detect a pressure differential across the basket.

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PRIOR ART

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Figure 3

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Figure 4

DOSING ASSEMBLY

The present invention relates to a dosing assembly for use in a closed loop heating or cooling system.

Heating systems in buildings very often use a working fluid (typically water) which is heated by a boiler and circulated under pressure through tubing to heat exchangers such as radiators to heat areas of the building. In a closed loop system the fluid is retained and recirculated, thus passing through the system any number of times. The fluid can become contaminated to form a sludge which can impair the efficient operation of the heating system. Contaminants include deposited calcium carbonate (limescale), by-products of corrosion in the system such as rust or magnetite, particulate impurities, and microbiological growths including fungi and yeast.

Sludge can affect performance of items exposed to the fluid, such as pumps and the heat exchangers of boilers, and can cause local blockages which impair system performance. If unmanaged, sludge can eventually necessitate flushing of the system with clean fluid and other remedial action to remove blockages and to replace damaged components.

To resist this fluid contamination, it is common to (a) incorporate filtration to capture contaminants and (b) treat the fluid chemically.

Chemical additives can be used among other things to inhibit corrosion, reducing build-up of corrosion products, to resist deposition of limescale, and to provide a biocidal effect reducing biological contamination. Antifreeze may also be used to prevent the damage that would result from freezing of water in pipes in a building whose heating system is left inactive for extended periods.

Filters used in heating systems may serve to block and physically capture particulates and/or may use magnets to capture ferrous material from the fluid.

Since a closed loop heating system is normally pressurised, it is desirable - and well known - to incorporate into such systems a dosing pot through which chemicals in liquid form are able to be introduced to the system without any need to de-pressurise or drain the system. A known configuration is depicted in Figure 1. The dosing pot 10 is formed as a vessel capable of withstanding the heating system's internal pressure and connectable via isolating valves between two points of the heating system, one at higher pressure than the other. In this example opening of an inlet-side isolating valve 12 connects the dosing pot 10 to a fluid supply line 14 of the heating system when open, and an outlet-side isolating valve 16 serves when open to connect the dosing pot 10 to a return line 18 of the system. The supply line 14 is, while fluid is flowing around the system, at greater pressure than the return line 18, so that when the isolating valves are open a small part of the total fluid flow is diverted through the dosing pot 10 to distribute chemicals contained in it in the fluid. In order to supply chemicals to the dosing pot 10, both isolating valves 12,16 are closed to isolate the dosing pot 10 from the heating system. Fluid is drained from the dosing pot 10 through a drain valve 20 to make room for the chemicals to be introduced. The chemicals, temporarily contained in a tundish 22, can then be released into the dosing pot 10 through a fill valve 24. The fill and drain valves 24, 20 are then closed and the isolating valves opened.

Since a portion of the fluid flow through the heating system is diverted through the dosing pot 10, it can additionally be used to house a filter. GB2503672B describes such an arrangement which is to be filled with chemicals in liquid form through a non-return valve, and which contains both a media filter and a magnetic collector for collecting ferromagnetic material.

Dosing pots are typically suited to use with chemicals in liquid form, but suitable chemicals are also commercially available which are supplied as solid bodies to be dissolved in the fluid. The type of dosing pot disclosed in GB2503762 is not suitable for use with solid chemicals. It has a lid which is bolted to the body of the pot and through which passes a dosing port formed as a narrow, internally threaded tube for connection to a supply of liquid treatment chemicals via a non-return valve and an isolating valve. The dosing port is not suitable for introduction of solid chemicals, being too narrow for this purpose.

While the above discussion relates to heating systems, similar challenges arise in relation to certain closed loop cooling systems and the invention is applicable to either.

In accordance with a first aspect of the present invention there is a dosing assembly according to claim

1.

Specific embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:Figure 1 is a schematic representation of a dosing pot arrangement belonging to the prior art;

Figure 2 is shows a dosing pot embodying the present invention, a dosing vessel being cut away to reveal interior components; and

Figure 3 corresponds to Figure 2 except that the dosing vessel is not cut away.

The dosing assembly 100 depicted in Figures 2 and 3 is for installation in a heating or cooling system to supply treatment chemicals to the system. It can be mounted in a side stream, which is to say that it need not receive the full flow through the system but can instead be connected, in the manner depicted in Figure 1, between two points in the system between which there is a pressure difference, causing a side stream flow through the dosing assembly 100. As well as dosing the fluid in the system, the dosing assembly 100 serves in the present embodiment to:

filter the system fluid to reduce contamination;

vent air from the fluid; and monitor pressure, and provide a warning if it deviates from an acceptable range.

All of these aspects will now be described in more detail.

The dosing assembly 100 comprises a dosing vessel 102 defining a dosing chamber 104. In the present embodiment the dosing vessel 102 is cylindrical, having an open upper end which is closed by a removable lid 106 in use, and a lower wall 108 which is domed in the present embodiment and through which passes an axially directed fluid outlet port 110. In the present embodiment the dosing vessel 102 has a stepped diameter so that above the dosing chamber 104 is a narrower neck portion 112 leading to the lid 106. A laterally directed fluid inlet port 114 is formed in the neck portion's side wall. Fluid normally flows in use in a downward direction from the fluid inlet port 114 to the fluid outlet port 110.

The lid 106 is able to be disengaged from the dosing vessel 102 by turning it, and is thus removable from the dosing vessel 102 to leave its upper end open. The dosing vessel will typically be depressurised before the lid 106 is removed, but in the event of misuse there is the possibility that the lid might be released while the dosing vessel 102 is exposed to the elevated pressure in the system. In the absence of some form of protection, this might result in the lid being forcibly propelled from the dosing vessel 102, and in subsequent uncontrolled venting of hot liquid from the vessel. As a safety feature, the lid 106 engages with the neck portion 112 of the dosing vessel 102 in such a manner that its disengagement involves first moving it to a captive pressure release configuration, in which a path is opened for release of pressure from the dosing chamber 104 but the lid 106 remains captively attached to the neck portion 112 and so cannot be ejected, and then moving the lid 106 to a full release configuration in which it is able to be removed from the dosing vessel 102. If, upon moving the lid to the captive pressure release configuration, the user observes that gas or liquid is being expelled, then the user is able to close the lid 106 and so prevent mishap. Suitable lid mechanisms are known to the skilled person. One such conforms to a DIN standard and is known in the trade as a DIN lid.

In Figure 2, the dosing vessel 102 is seen to contain a bubble coalescing device 116 and a basket 118.

The basket 118 is disposed in the dosing chamber 104 but can be removed from the dosing vessel 102 through its open upper end, while the lid 106 is not in place. In the present embodiment it is generally cylindrical in form, having a side wall 120 whose lower end is closed by an end wall 122 and whose upper end 124 is open. The walls of the basket 118 are permeable to fluid. They may for example comprise wire mesh. Alternatively they may comprise metal or other sheet material provided with multiple small openings. Whatever its construction, the basket serves in use to receive and carry treatment chemicals in solid form without preventing fluid flow through the dosing chamber 104. Flow from the fluid inlet port 114 to the fluid outlet port 110 passes through the basket 118 containing the chemicals, ensuring that they are exposed to the flow and so become dissolved and distributed through the fluid in the system.

The basket 118 has in the present embodiment an outwardly turned upper lip 126 which seats on an internal shoulder of the dosing vessel 102 to maintain the basket in position.

The function of the bubble coalescing device 116 is to cause small air bubbles in the fluid flow to coalesce forming larger bubbles which will rise to an automatic air vent 128 which is carried by and passes through the lid 106. In this way the dosing assembly 100 enables air to be vented from the system. Suitable automatic air vents 128, able to release air without problematic loss of system pressure, are in themselves well known in the art.

In the present embodiment the bubble coalescing device comprises a ring structure which offers large openings for flow of fluid, but also has a large surface area for collection of bubbles. Suitable ringshaped metal or plastics structures are sold under the generic name Pall rings.

The dosing assembly 100 can be connected in a heating system in the manner depicted in Figure 4 with its fluid inlet port 114 being led via inlet-side isolating valve 412 to a high pressure point in the system, its fluid outlet port 110 being led to both (a) drain valve 420 and (b) outlet-side isolating valve 416. Comparing Figure 4 with Figure 1, note that no tundish 22 or fill valve 24 is required in use of the dosing assembly 100 embodying the present invention.

In use, in order to dose the system with chemicals the dosing vessel 102 is first isolated from system pressure by closing the isolating valves 412 and 416. Some fluid can be drained from the dosing vessel 102 through the drain valve 420, which serves to de-pressurise the vessel. The lid 106 is then removed and the coalescing device 116 and the basket 118 can be removed from the dosing vessel 102 through its open upper end simply by lifting them out. Treatment chemicals in solid form can be placed in the basket 118. Chemicals in liquid form can simply be poured into the dosing vessel 102. The basket 118 and the coalescing device 116 are then returned to the dosing vessel 102, the lid 106 is replaced and engaged to seal the vessel, and the isolating valves 412, 416 are opened to enable fluid flow through the dosing vessel 102 and so distribute the chemicals through the system.

After dosing, the dosing assembly 100 can be used as a filter. For this purpose, a suitable filter such as a bag filter is placed in the basket 118. The bag filter may be suspended across the open upper end

124 of the basket, which serves to support the filter in use.

With reference to Figure 3, provision is made for sensing pressure within the dosing vessel 102. In the present embodiment there is a first pressure sensor housed in a first sensor port 130 upstream of the basket 118 and a second pressure sensor housed in a second sensor port 132 downstream of the basket 118. Both provide output signals to an electronic controller 134. The pressure data may in principle be output in a variety of different ways. The dosing assembly 100 may for example be provided with a display for the data. But in the present embodiment the pressure data is supplied to a building management system which monitors the data and provides a warning signal in the event that pressure indicative of a fault is detected. Specifically, the pressure difference between the two sensors if monitored. An excessive pressure drop is likely to result from a build-up of material in the filter, and so may be interpreted as an indication that servicing or renewal of the filter is required.

The dosing vessel 102 is to be clad in a thermally insulating jacket, to minimise heat loss. This feature is not shown in the drawings. It presents a challenge in that it is desirable to be able to detect visually any weeping or more serious leakage from the dosing vessel 102. The jacket, by covering the dosing vessel, may hide the signs of such problems. To address this challenge the jacket preferably incorporates an element which undergoes a visible change upon contact with water. In particular, the element in question may change colour upon contact with water. A suitable element may comprise a pH indicator applied to the exterior of the jacket. The system fluid is typically alkaline, and so causes a visible change to the colour of the pH indicator if it contacts the treated surface of the jacket, giving a visible warning of weeping or leakage.

Claims (12)

1. A dosing assembly for connection to a heating or cooling system, the dosing assembly comprising a dosing vessel which defines a dosing chamber and which is provided with a fluid inlet port communicating with the dosing chamber and connectable to a higher pressure part of the system, and a fluid outlet port communicating with the dosing chamber and connectable to a lower pressure part of the system, the dosing vessel having an upwardly facing opening communicating with the dosing chamber, and a removable lid for closing and sealing the said opening, the assembly further comprising a basket which is insertable in and removable from the dosing chamber though the said opening, the basket being configured to receive and retain fluid treatment chemicals in solid form, and when disposed in the dosing chamber to maintain the said solid form chemicals in a flow path through the dosing chamber from the fluid inlet port to the fluid outlet port, the basket being permeable to fluid flowing along the flow path and enabling the solid form chemicals to be exposed to fluid flow and so to be dissolved in the fluid and carried through the system.

2. A dosing assembly as claimed in claim 1 in which the lid is configured to be engageable with and disengageable from the dosing vessel by turning the lid.

3. A dosing assembly as claimed in claim 1 or claim 2 in which the disengaging the lid involves first moving it to a captive pressure release configuration, in which a path is opened for release of pressure from the dosing chamber but the lid remains captively attached and so cannot be ejected, and then moving the lid to a full release configuration in which it is able to be removed from the dosing vessel.

4. A dosing assembly as claimed in any preceding claim further comprising a filter received in the basket to filter fluid passing from the fluid inlet port to the fluid outlet port.

5. A dosing assembly as claimed in claim 4 in which the filter is a bag type filter.

6. A dosing assembly as claimed in any preceding claim in which an open upper end of the basket is shaped to rest stably upon a complementary feature within the dosing chamber to support and locate the basket.

7. A dosing assembly as claimed in any preceding claim in which the filter has a radially outwardly projecting lip to rest upon a radially inwardly projecting feature within the dosing chamber to support and locate the basket.

8. A dosing assembly as claimed in any preceding claim in which the lid incorporates an automatic air vent for exhausting air from within the dosing chamber.

9. A dosing assembly as claimed in claim 8 in which the dosing vessel houses a bubble coalescing device which promotes coalescing of bubbles and their consequent exhaustion from the dosing chamber.

10. A dosing assembly as claimed in claim 9 in which the bubble coalescing device is disposed above the basket.

5

11. A dosing assembly as claimed in any preceding claim further comprising a pressure sensor arranged to sense pressure in the dosing chamber.

12. A dosing assembly as claimed in any preceding claim in which the dosing vessel is provided with a thermally insulating jacket comprising a material which changes colour in response to contact with the system fluid.

22 03 18

Intellectual

Property

Office

Application No: Claims searched:

GB 1709706.4 1-14

12. A dosing assembly as claimed in any preceding claim comprising two pressure sensors arranged to sense pressure in the dosing chamber upstream and downstream respectively of the basket.

13. A dosing assembly as claimed in claim 12 connected to an electronic system configured to detect 10 when a difference between pressures sensed by the two sensors exceeds a predetermined threshold.

14. A dosing assembly as claimed in any preceding claim in which the dosing vessel is provided with a thermally insulating jacket comprising a material which changes colour in response to contact with the system fluid.

AMENDMENTS TO THE CLAIMS HAVE BEEN FILED AS FOLLOWS

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1. A dosing assembly for connection to a heating or cooling system, the dosing assembly comprising a dosing vessel which defines a dosing chamber and which is provided with a fluid inlet port 5 communicating with the dosing chamber and connectable to a higher pressure part of the system, and a fluid outlet port communicating with the dosing chamber and connectable to a lower pressure part of the system, the dosing vessel having an upwardly facing opening communicating with the dosing chamber, and a removable lid for closing and sealing the said opening, the assembly further comprising a basket which is insertable in and removable from the dosing chamber though the said 10 opening, the basket being configured to receive and retain fluid treatment chemicals in solid form, and when disposed in the dosing chamber to maintain the said solid form chemicals in a flow path through the dosing chamber from the fluid inlet port to the fluid outlet port, the basket being permeable to fluid flowing along the flow path and enabling the solid form chemicals to be exposed to fluid flow and so to be dissolved in the fluid and carried through the system, the lid being configured 15 such that its removal requires first moving the lid to a captive pressure release configuration, in which a path is opened for release of pressure from the dosing chamber but the lid remains captively attached and so cannot be ejected, and then moving the lid to a full release configuration in which it is able to be removed from the dosing vessel, and the lid incorporating an automatic air vent for exhausting air from within the dosing chamber.

20 2. A dosing assembly as claimed in claim 1 in which the lid is configured to be engageable with and disengageable from the dosing vessel by turning the lid.

3. A dosing assembly as claimed in any preceding claim further comprising a filter received in the basket to filter fluid passing from the fluid inlet port to the fluid outlet port.

4. A dosing assembly as claimed in claim 4 in which the filter is a bag type filter.

25 5. A dosing assembly as claimed in any preceding claim in which an open upper end of the basket is shaped to rest stably upon a complementary feature within the dosing chamber to support and locate the basket.

6. A dosing assembly as claimed in any preceding claim in which the filter has a radially outwardly projecting lip to rest upon a radially inwardly projecting feature within the dosing chamber to support

30 and locate the basket.

7. A dosing assembly as claimed in claim 6 in which the dosing vessel houses a bubble coalescing device which promotes coalescing of bubbles and their consequent exhaustion from the dosing chamber.

8. A dosing assembly as claimed in claim 7 in which the bubble coalescing device is disposed above the basket.

5 9. A dosing assembly as claimed in any preceding claim further comprising a pressure sensor arranged to sense pressure in the dosing chamber.

10. A dosing assembly as claimed in any preceding claim comprising two pressure sensors arranged to sense pressure in the dosing chamber upstream and downstream respectively of the basket.

11. A dosing assembly as claimed in claim 10 connected to an electronic system configured to detect 10 when a difference between pressures sensed by the two sensors exceeds a predetermined threshold.