GB2418710A

GB2418710A - A pump unit with an ultra-violet lamp

Info

Publication number: GB2418710A
Application number: GB0525895A
Authority: GB
Inventors: Kaushik Ishwarbhai Patel; Phong Yui Yung
Original assignee: Hozelock Ltd
Current assignee: Hozelock Ltd
Priority date: 2004-06-10
Filing date: 2005-06-03
Publication date: 2006-04-05
Also published as: GB0525895D0

Abstract

A pump unit for placing in a pond, the unit comprising 10 a housing 40 in which is housed an electrical pump 70 and UV lamp 80. In operation the pump causes water from the pond to flow past the UV lamp so as to be exposed to the UV light. Such UV "filters" are used to remove the green colour due to algae growth, by causing the algae cell walls to rupture, and thus clarify the water. The pump unit may be submersible in water. The UV lamp may have a cover 86 of a material, such as quartz, which tends to allow UV light to pass through it. The pump unit may also have a mechanical filtering means (50 figure 3) removably located in the housing and a bypass means 52 for use if the filter becomes clogged. The pump unit may have a fountain 90 outlet and a flow control means 102 to variably control the flow through the bypass outlet and/or the fountain. Independently claimed are a pond pump and filter; a pond pump with variable flow control means and a pond pump with fountain outlet and bypass means.

Description

A Pump Unit This invention relates to a pump unit for placing in a pond.

The water in ponds, such as ornamental ponds found in domestic gardens, can become, or give the appearance of being, dirty or polluted. For example, pond water may take on a green colour due to the growth of algae or similar organisms in that water. Pond water may also become dirtied with non-living solid matter.

To overcome this problem, pond filters are available for positioning near to a pond and for receiving a flow of water from the pond. The filters filter water received from the pond and then return the filtered water to the pond. Water is received from the pond along a hose running from a pump and is returned to the pond by way of another hose.

Ultra-violet (W) filters are also available. These include a UV lamp for exposing water flowing through the W filter to W light. The UV filters are also for positioning near to a pond and may be positioned to receive water from a pump and to supply water to a pond filter of the kind just described.

It is an object of this invention to improve the prior art.

According to a first aspect of this invention, there is provided a pump unit for placing in a pond, the unit including a housing in which is housed an electrical pump and an electrical W lamp, wherein the unit is arranged such that the pump can draw water from the pond and is operable to cause that water to flow past the W lamp, so as to be exposed to W light therefrom, before rejoining the pond.

S By providing a pump unit that includes both an electrical pump and a W lamp, a neat and supple unit results that removes the need for a separate, unsightly W filter situated near to the pond, together with the associated water hoses running to and from the pond. Instead, the W lamp is placed out of sight in the pond.

The umt may be arranged such that the pump draws water from the pond past the W lamp and then into an inlet of the pump unit. The unit maybe arranged such that the pump draws water from the pond and pumps that water, from an outlet ofthe pump, past the W lamp.

The unit may be arranged so that the pump and the lamp may be submerged in water.

The unit may be arranged so that the unit may be submerged in water.

The unit may be arranged such that electrical components of the pump are contained in sealed container which is sealed against the ingress of water. The unit may be arranged such that electrical components of the lamp are contained in sealed container which is sealed against the ingress of water.

The unit may be arranged such that electrical components of the pump and of the lamp are contained together in a sealed container in the housing, the sealing being > against the ingress of water. All of the electrical components of the pump and the lamp may be contained in the container. This allows the pump and the lamp to be powered by power from a single power lead to the container. Typically, the container is not of one-piece construction and may, instead, be formed from separable components. The sealed container may have a single power lead extending therefrom to supply electrical power to both of the pump and the lamp. The use of a single power lead, rather that a respective lead for each of the pump and the lamp simplifies construction of the unit and also simplifies installation of the unit in a pond. It may also be considered a safer configuration as, the fewer the number of power leads, the lo less is the likelihood of one being inadvertently damaged, for example by a lawn mower or other garden cutting apparatus, and conductors of the lead being thereby exposed.

A single sealed container is also advantageous in that it can require fewer seals than would, for example, two sealed containers.

The sealed container may be at least partly constituted by a removable cover for the UV lamp, the cover being removable from the remainder of the sealed container. The cover is preferably at least partly of a material, such as quartz, that tends to allow W light to pass readily therethrough. Preferably the cover is a quartz tube, closed at one end and with mounting structure at the other, open, end for sealedly and releasably mounting the cover to the remainder of the container.

The unit may be arranged such that the major dimension of the UV lamp extends in l the direction of water flow therepast. Preferably, where the W lamp is tubular, the unit is arranged such that water flow past the lamp is substantially axial and, preferably, is all around the lamp in order to maximise exposure of the water to W light emitted by the lamp.

The unit may also include mechanical filtering means and may be arranged such that the pump causes the water drawn from the pond to pass through those means such that the water is filtered thereby. The unit may be arranged such that the filtering means filters water drawn from the pond before or after that water reaches the pump andfor before or after that water flows past the lamp. The filtering means may include apertures formed in the housing of the unit and through which water from the pond is drawn by the pump. The apertures may be slots. The filtering means may include a filter member that is removably locatable in the housing. The filter member may include a mesh member. The mesh member may include a network of strands running in three dimensions between which water is drawn for filtering. The filter member may include a foam member for filtering water drawn therethrough.

Preferably, the filtering means is arranged such that water is drawn from the pond therethrough before passing through the pump. This minimises the risk of the pump being clogged by solid matter or of the pump chopping up that matter into pieces.

Chopping the matter into pieces is disadvantageous as the pieces may be small enough to avoid being caught by the mechanical filtering means.

The unit may include a bypass for allowing water drawn from the pond to bypass the filtering means when water flow though that means is hindered by at least partial s clogging thereof. The bypass may include a valve. Preferably, the valve is arranged such that at least partial clogging of the filter means increases a pressure difference across the valve such that the valve opens and allows water drawn from the pond to pass therethrough and to thereby bypass at least part of the filter means. Where the filtering means includes a filter member, that member may include a bypass flow path therethrough in which the valve is situated. A bypass member may be provided that defines a bypass flow path with the valve situated therein. The valve may include a thin flap of material that is resiliently biased in a closed position and may be situated at an outlet side of the bypass flow path. The bypass member may be arranged to receive the filter member such that the bypass flow path extends through the member.

The housing may include a lid portion that is removably attachable to the remainder of the housing. The lid portion preferably is adjacent the filter medium such that removal of the lid portion facilitates access to the filter medium for inspection and/or removal thereof. The lid portion may include at least one catch for releasably attaching that portion to the remainder of the housing. The catch may be a sprung catch that is Repressible by a user to allow removal of the lid portion.

The unit may include biological filtering structure arranged with a high surface area to volume ratio and arranged in the housing such that water drawn from the pond is caused to flow over and around the structure. Organisms present in the water will tend to grow on the surface of the structure and to clean water passing thereover and therearound. Preferably, the biological filtering structure is arranged in the housing such that water is drawn thereover and therearound after having passed through the filter means and before passing through the pump.

The unit may include a water outlet for creating a fountain, hereinafter referred to as the "fountain outlet". The fountain outlet may be an outlet from the unit for at least some of the water drawn from the pond by the pump. Preferably, the unit is arranged such that the fountain outlet receives water that has already flowed past the W lamp.

This is advantageous in that water which has been exposed to W light from the lamp is then dispersed by the fountain outlet about the pond, rather than just in the vicinity of the unit. This tends to reduce the time taken for or, at least increase the likelihood of, substantially all of the water in the pond being drawn through the unit and being exposed to W light from the lamp.

The unit may include a bypass outlet arranged to provide an outlet for at least some of the water drawn from the pond, so as to bypass the fountain outlet and rejoin to pond without forming a fountain. Preferably, the bypass outlet receives water that has already flowed past the lamp. The unit may include variable flow control means to variably control the flow of wata though the bypass outlet. The variable flow control means may be arranged to be operable between a state in which flow through the bypass outlet is prevented and a state in which all wata drawn from the pond is allowed to pass through the bypass outlet, and operable at states thaebetween.

Preferably, however, the variable flow control means is arranged so as to always allow at least some flow thaethrough. This ensures that, should the fountain outlet become clogged, wata may still exit the unit. The variable flow control means may be arranged to have the effect of controlling the height of the fountain from the fountain outlet. The variable flow control means may comprise a rotatable ring.

The bypass outlet may be positioned in the unit away from an inlet thereto through which water is drawn from the pond by the electrical pump. The bypass outlet may be positioned away from the mechanical filtering means, and preferably is positioned away from the apertures formed in the housing and through which water is drawn into the unit.

The housing may include outlet structure that at least partly defines the fountain outlet, the outlet structure being moveable relative to the remainder of the housing so as to allow water exiting the unit from the fountain outlet to be directed in a preferred direction. The outlet structure may be so moveable by the provision of a ball joint between the outlet structure and the remainder of the housing.

The unit may be arranged with a base portion and a projecting upper portion upstanding therefrom. The filtering means may conveniently be housed in the base portion, together, optionally, with the pump. The W lamp may conveniently be housed in the upper portion, with the fountain outlet preferably arranged at the distal end of that portion.

The outlet structure may be removable and an obscuring plate may be provided in the housing to obscure viewing of the UV lamp when the outlet structure is removed.

The ball joint may form part of a ball joint assembly comprising the ball joint and the obscuring plate. The ball joint assembly may be captured in the housing. This can help prevent accidental viewing of the UV lamp. The obscuring plate may be dimensioned so that it is unable to pass through an aperture in the housing through which the ball joint projects. The obscuring plate may be mounted to the ball joint after the ball joint has been mounted in the housing. The obscuring plate may be fixed by a screw to the ball joint. Alternatively the obscuring plate may be clipped to or push fitted to the ball joint.

The unit may comprise a takeoff outlet for supplying water via a hose to a remote outlet. The remote outlet might be used to provide a waterfall or other water feature.

The takeoff outlet may be distinct from any fountain or bypass outlet provided. The unit may comprise variable flow control means for variable control of water flow through the takeoff outlet. This variable flow control means may comprise a user operable rotatable ring. The rotatable ring may surround a portion of the housing and may be incomplete. This variable flow control means may comprise a collar control.

Preferably the unit is arranged so that the takeoffoutlet is positioned in the flow path so that water leaving via the takeoff outlet will have passed the W lamp and preferably any other filter means included in the unit. The unit may comprise a takeoff outlet conduit providing a passage from the downstream end of the W lamp to the takeoff outlet. The takeoff outlet conduit may comprise an inlet disposed at the downstream end of the UV lamp. The variable flow control means may comprise a closure member for closing, by controllable degrees, the inlet of the takeoff outlet conduit. The takeoff outlet may disposed towards the base of the unit. The takeoff outlet may be disposed closer to a base of the unit than is the distal end of the W lamp. This can help with stability.

Where there are variable control means for the takeoff outlet and the fountain bypass outlet, the manually operated actuators, for example rotatable rings/control collars may be disposed adjacent one another. The bypass may be arranged so that water exiting via the bypass passes between the two control rings.

According to another aspect of this invention, there is provided a pond pump unit which comprises a housing in which is housed an electrical pump and a filter, wherein the unit is arranged such that the pump can draw water from the pond and is operable to cause that water to flow through the filter before rejoining the pond and wherein the unit includes a bypass for allowing water drawn from the pond to bypass the filter when water flow through the filter is hindered by at least partial clogging thereof According to another aspect of this invention, there is provided a pond filter unit which comprises a housing in which is housed a filter, wherein the unit is arranged such that water drawn from the pond flows through the filter before rejoining the pond and wherein the unit includes a bypass for allowing water drawn from the pond to bypass the filter when water flow through the filter is hindered by at least partial clogging thereof.

The bypass may comprise the additional features described above in relation to the first aspect of the present invention. In particular, the bypass may comprise a bypass member at least partially defining a bypass flow path and a flap of material that is resiliently biased in a closed position at an outlet side of the bypass flow path.

Similarly the pond pump unit or pond filter unit may comprise a fountain outlet.

According to another aspect of this invention, there is provided a pond pump unit which comprises a housing in which is housed an electrical pump wherein the unit is arranged such that the pump can draw water from the pond and is operable to cause that water to flow out of the housing via an outlet, the unit comprising variable flow control means for variably controlling flow of water from the outlet, the variable flow control means comprising a rotatable ring.

The rotatable ring may surround a portion of the housing of the unit and be rotatable relative thereto. The rotatable ring can be considered as a collar control.

According to another aspect of this invention, there is provided a pond pump unit which comprises a housing in which is housed an electrical pump wherein the unit is arranged such that the pump can draw water from the pond and is operable to cause that water to flow out of the housing via a fountain outlet, the unit further comprising a bypass outlet arranged to provide an outlet for at least some of the water drawn from the pond, so as to bypass the fountain outlet.

According to yet another aspect of this invention, there is provided a pond fountain unit which comprises a housing having an inlet through which water from the pond can pass into the housing and a fountain outlet through which water flow out of the housing, the unit further comprising a bypass outlet arranged to provide an outlet for at least some of the water passing into the housing, so as to bypass the fountain outlet.

The pond pump unit or pond fountain unit may comprise one or more of the features described above in relation to the first aspect of the invention. In particular, the pond pump unit or pond fountain unit may comprise a filter.

Specific pump units in which the invention is embodied are described now by way of example only and with reference to the accompanying drawings, in which: Figure 1 is a perspective view of a first pump unit; Figure 2 is a perspective view of the unit of Figure 1 with part of a housing thereof removed to show internal detail; Figure 3 is a perspective view of mechanical filtering means of the pump unit of Figure 1; Figure 4 is another perspective view of the pump unit of Figure 1; Figure 5 is a sectional view of the pump unit of Figure 1; Figure 6 is a sectional view of a second pump unit which includes a take off outlet; l and Figure 7 is an exploded view of part of the pump unit of Figure 6 which illustrates a flow control mechanism for the take off outlet. s

Figure 1 shows a pump unit 10 having a squat cylindrical base portion 20 and a narrower cylindrical upper portion 30 that projects from the base portion 20 so as to be upstanding from it. The upper portion 30 is positioned towards the periphery of the base portion 20. The pump unit 10 is for placing in a pond so as to be submerged in water of the pond.

The pump trait 10 has a plastic housing 40 that houses components (not shown in Figure 1) of the unit 10. The housing 40 is made up of a base housing 40a that is formed to define the outer shape of the base portion 20, and an upper housing 40b that is formed to define the outer shape of the upper portion 30. The majority of the upper part of the base housing 40a forms a removable lid 42 that is removable from the remainder of the base housing 40a. The lid 42 includes two catches (only part of which is visible at 44) that are for releasably securing the lid 42 to the remainder of the base housing 40a. Each of the catches has a respective button portion 44 that projects through an aperture formed in the lid 42 for operation by a user to disengage the respective catch from the remainder of the base housing 40a and thereby allow removal of the lid 42.

The base housing 40a is formed with many apertures through it in the form of slots 46. The slots 46 are formed in the lid 42 and in the side of the base housing 40a adjacent the lid 42.

Figure 2 shows the pump unit 10 with part of the housing 40 removed in order to show the inside of the unit 10. With reference to Figure 2, the pump unit 10 includes mechanical filtering means in the form of a foam block 50, biological filtering structure in the form of"biomedia" 60, an electrical pump 70, a W lamp 80, a fountain outlet 90 and a bypass outlet 100.

The foam block 50 is generally semi-circular in cross-section. The block SO is arranged in the squat cylindrical base portion 20 against the outside of the base portion 20 and underneath the lid 42. The block 50 is shaped to substantially fill the inside of the unit 10 that is beneath the lid 42. The block 50 is made of a coarse foam-like material that is arranged to mechanically filter water passing through it by straining solid matter from that water.

The foam block 50 is supported on a bypass member 52 on which the block 50 is seated. The bypass member 52 is formed of moulded plastic and includes a base portion 54 and a cylindrical tube 56. The base portion 54 is shaped as the base of the block 50 and includes many apertures 55 through it. The base portion 54 also includes a peripheral wall that follows snugly the sides of the block 50. The cylindrical tube 56 is upstanding from the base portion 54 and is accommodated in the block 50 by way of a cylindrical aperture 51 extending through the block 50, from its base to its top. The tube 56 extends through the aperture 51. The foam block 50 and the bypass member 52 are also shown in Figure 3. As shown in Figure 3, the lower end of the tube 56 is provided with a flap valve 58. The valve 58 is arranged to allow liquid flow in a downwards direction only, and only when a pressure differential across the valve (i. e. the difference between pressure at the inlet side of the valve and pressure at the outlet side of the valve) is above a certain pressure difference.

With reference to Figure 2, the unit 10 includes a chamber 62 in the base portion 20 that communicates with the underside of the base portion 54 of the bypass member 52. This chamber 62 is generally underneath and extends to each side of the upper portion 30. The chamber 62 accommodates the biomedia 60. The biomedia 60 are plastic structure with high surface area to volume ratio and, in this embodiment, take the form of six ball-like objects formed of many intersecting, jagged, generally planar surfaces.

The electrical pump 70 is positioned in the housing 40 so as to be in the chamber 62 in which the biomedia 60 are also accommodated. The electrical pump 70, however, is more centrally positioned so as to be underneath the upper portion 30. Thus, the biomedia 60 are positioned to the sides of the electrical pump 70. Casing 72 of the electrical pump 70 forms a barrier at the base of that upper portion 30 between the chamber 62 and the inside of the upper portion 30 of the unit 10. The casing 72 also defines an inlet of the electrical pump (not visible in Figure 2) that extends into the chamber 62 and an outlet (not visible in Figure 2) that extends into the upper portion 30. The electrical pump 70 may be arranged to receive a mains voltage at, for example, 240V AC or l l OV AC; or a low voltage at, for example, 24V AC. In this embodiment, the electrical pump 70 operates at a mains voltage.

The UV lamp 80 is positioned inside the upper portion 30 of the pump unit 10 and is an arrangement of several parts. A base 82 of the lamp 80 is joined to the pump casing 72 so as to be an extension of that casing 72 and so as to project therefrom upwards into the upper portion 30. The base 82 houses an electrical socket (not shown in Figure 2) into which a UV bulb 84 of the W lamp 80 is releasably locatable. The lamp 80 also includes a removable cover in the form of a quartz tube 86, closed at one end and fitted with a bayonet fitting 87 at the other. The bayonet fitting 87 and the base 82 are such that the fitting 87 can be received in the base 82 and twisted into a position in which a watertight seal is created between the base 82 and the fitting 87, and hence also the quartz tube 86. A screw 88 is provided for keeping the bayonet fitting 87, and hence the quartz tube 86, in place. Thus, the quartz tube 86, with the W bulb 84 inside, project upwardly from the base 82 into and through the upper portion 30 of the unit 10.

Taken together: the casing 72 of the pump 70; and the base 82, bayonet fitting 87 and quartz tube 86 of the UV lamp 80, form a sealed container in which all the electrical components ofthe pump unit 10 are housed in a watertight fashion. This allows the pump unit 10 to have a single electrical power lead, shown at 15 in Figure 4 running thereto. The power lead 1 S enters the base portion 20 of the unit 10 via a suitable aperture 16, and from there enters the sealed container via an aperture (not shown) in the casing 72 of the pump 70.

With reference to Figure 5, the upper end of the upper portion 30 of the pump unit 10 is formed into a socket 32 for receiving a ball joint 34. The ball joint 34 is a short length of plastic tube with the mid portion of its outer surface formed to resemble the outer surface of a sphere. A removable threaded collar 36 is provided for releasably and variably securing the ball joint 34 to the upper end of the upper portion 30, that upper end being formed with a cooperating thread. When secured in this way, an upper end 38 of the ball joint 34 projects beyond the collar 36. The upper end 38 of the ball joint 34 is threaded.

A fountain outlet 90 is provided for attachment to the threaded upper end 38 of the ball joint 34. This outlet 90 is shown attached in Figure 2. The fountain outlet 90 includes a pipe 92 with a nozzle portion 94 at one end. The other end of the pipe 92 is threaded and is for cooperating with the threaded upper end 38 of the ball joint 34 for releasable attachment to that end 38. The nozzle portion 94 is formed with holes therethrough arranged to direct water pumped therethrough into a jet of one or more streams.

The upper portion 30 of pump unit 10 includes a bypass outlet 100 towards its upper end, but below the fountain outlet 90, the ball joint 34 and the collar 36. The bypass outlet 100 includes an outlet aperture (not shown) in the upper casing 40b of the upper portion 30 that allows communication between the inside of the upper portion and the outside. The bypass outlet 100 also includes a rotatable ring 102 that surrounds the upper portion 30 in the region of the outlet aperture. This region of the upper portion 30 is of reduced diameter, such that the ring 102 can be accommodated around that region so as to be flush with the surrounding outside surface of the upper portion 30. The ring 102 is formed and fitted to the upper portion 30 so as to be rotatable between a position in which the outlet aperture is almost closed by the ring 102 and a position in which the outlet aperture is open, and rotatable to positions between these two extremes.

For operation, the pump unit 10 is placed in a pond, such as a pond in the garden of a house. The pump unit 10 is positioned in the pond such that the outlet aperture in the upper portion 30 of the unit 10 is below the pond's water line and such that the nozzle 94 is above the water line. The electrical lead 15 is then connected, in this embodiment, to a mains source of electrical power. This causes the unit 10 to operate.

operation, the electrical pump 70 and the W lamp 80 receive power via the lead and operate. The pump 70 reduces the pressure in its inlet below the ambient pressure of pond water surrounding the pump unit 10. This causes pond water to be drawn towards and into the inlet. Thus, water from the pond is drawn through the slots 46 in the base housing 40a, through the foam block 50 and the apertures 55 of the base portion 54 on which the block 50 sits, into the chamber 62 in the base portion 20 and, from there, into the pump 70 via its inlet. As the water is drawn along this flow path, the slots 46 in the base housing 40a serve to strain large pieces of solid matter from the water as it is drawn therethrough; and the foam serves to subsequently strain finer pieces of solid matter from the water. In the chamber 62, the water is drawn over and around the many surfaces of the biomedia 60 before entering the pump 70. Micro-organisms on the surfaces of the biomedia 60 tend to operate on the water to clean it further by feeding on ammonia and converting it into nitrite and then nitrate.

Water that passes into the operating electrical pump 70 exits the pump 70 via its outlet into the upper portion 30 ofthe pump unit 10. The pump 70 increases the pressure of water at its outlet to a pressure above the ambient pressure of water in the pond. Thus, water flows from the outlet, up the upper portion 30, around and past the operating UV lamp 80 to the upper end of the upper portion 30. From here, some of the water flows through the ball joint 34, up the pipe 92 of the fountain outlet 90 to exit the unit 10 in one or more jets via the nozzle 94, thereby forming a fountain of water before returning to the pond. The remainder of the water flows through the aperture ofthe bypass outlet 100 to thereby exit the unit 10 and rejoin the remainder of the water in the pond. As the water flows around and past the W lamp 80, that lamp 80 exposes the water and its contents to UV light. The UV light tends to cause the cell walls of algae in the water to rupture, which in turn causes the algae to gather together in groups that either sink to the bottom of the pond or are caught by mechanical filtering. The rotatable ring 102 of the bypass outlet 100 is rotatable to vary the

amount of water that exits the pump unit 10 via that bypass outlet 100 so as to bypass the fountain outlet 90. Rotating the ring 102 to open the bypass outlet 100 to its fullest extent results in substantially all ofthe water from the pump 70 exiting the unit 10 via the bypass outlet 90. This feature may be used when only a small fountain of water is required. Alternatively, the ring 102 can be rotated to close the bypass outlet to its fullest extent. This, however, does not completely close the bypass outlet 100, but still allows some water from the pump 70 to exit the unit 10 therethrough.

This ensures that water can still flow through the unit 10 even if the nozzle 94 of the fountain outlet 90 were to become blocked. Selectively rotating the ring 102 to positions between these two extremes allows the height of the fountain of water produced by the unit 10 to be varied in a controlled manner.

In the event that the foam block 50 becomes clogged by solid matter trapped therein, an increased pressure differential is created across the valve 58 in tube 56 of the bypass member 52 on which the block 50 sits. This causes the valve 58 to open and to allow water to flow along the tube 56 and into the chamber 62 and the pump 70 in the base portion 20. Thus, the foam block 50 is bypassed when clogged. Again, this allows the pump unit 10 to continue to operate and, in particular, to continue to expose pond water to the W lamp 80 when the foam block 50 is at least partially clogged.

Should the foam block 50 become blocked in the way described, it can be removed and either cleaned or replaced. To remove the foam block 50, the lid 42 of the base portion 20 is first removed from the remainder of that portion 20 by pressing on the two button portions 44 of the catches, and lifting the lid 42. This allows access to the foam block 50. The foam block 50, together with the bypass member 52 on which the foam block 50 sits, can then be removed from the base portion 20. The foam block and the bypass member 52 would then be separated from one another in order to allow cleaning or replacement of the foam block 50. The pump unit 10 is re assembled by carrying out this process in reverse.

The UV bulb 84 may also be removed for, for example, replacement. It this is to be done, electrical power to the pump unit 10 should first be cut off. The unit 10 may then be removed from the pond. Access to the W lamp 80 is gained by removing the upper housing 40b around the upper portion 30 of the unit 10. This part of the housing 40 is twist mountable onto the remainder of the housing 40 (i.e. the base housing 40a) and is easily removed once a locating screw (shown at 41 in Figure 4) is removed. The quartz tube 86 can then be removed by unscrewing the screw 88 in the bayonet fitting 87 and twisting that fitting 87. The UV bulb 84 can then be removed, replaced and the process reversed to re-assemble the pump unit 10.

Figure 6 shows a pump unit 1000 which is similar to the pump unit 10 shown in Figures 1 to 5. The pump unit 1000 shown in Figure 6 is arranged for use in a larger pond than that shown in Figure 5 but in many respects is the same, or substantially the same, as the pond unit 10 shown in Figures 1 to 5. Therefore, detailed description of the majority of the pump unit 1000 shown in Figure 6 will be omitted and the same reference numerals are used to refer to the corresponding parts with the exception that 1000 is added to each reference numeral so that 20 becomes 1020 and so on.

The base portion 1020 of the pump unit 1000 shown in Figure 6 is basically the same as that shown in Figures 1 to 5 except that it has increased dimensions. Again this base portion 1020 is arranged to stand submerged in the water of a pond. Indeed, as is the case for the pump unit shown in Figures 1 to 5, the whole unit is arranged so as to be submersible in water with the tip of a fountain outlet (not shown in Figure 6) at or near the surface.

In the pump unit 1000 shown in Figure 6 there is again the cylindrical upper portion 1030 which is narrower than the squat cylindrical base portion 1020. In this pump unit 1000 a take offoutlet 1001 is provided in the upper portion 1030. This take off lo outlet 1001 is arranged to allow a supply of filtered water to leave the pump unit 1000 via a suitable hose connected to the take off outlet 1001 and to be fed by the hose to a remote outlet, for example so as to form a waterfall feature.

The pump unit 1000 also includes a flow control for controlling the flow which leaves the pump unit lOOO via the take off outlet 1001. As most clearly seen by reference to Figure 7 as well as Figure 6, a take off outlet conduit 1002 is provided on the inside surface of the upper housing 1040b of the upper portion 1030. This conduit 1002 has an inlet 1002a towards its upper end and feeds into the take off outlet 1001 at its lower end. By reference to Figure 6 it can be seen that the inlet 1002a to the conduit 1002 is at the downstream end of the W lamp 1080 so that water entering the conduit 1002 to leave the pump unit 1000 via the take off outlet 1001 will have passed the W lamp 1080.

In this pump unit 1000, as well as a rotatable ring or collar control 1102 for controlling a by-pass outlet 1100 for allowing water to by-pass the fountain outlet 1090 (in the same way as in the first pump unit shown in Figures I to 5), there is provided a second rotatable ring or collar control 1003 which is operable by a user to control the flow allowed out of the take off outlet 1001. The collar control 1003 for the take off outlet 1001 comprises a depending tongue 1003a which is best seen in Figure 7 and which is arranged to substantially blank off the inlet 1002a to the conduit 1002 if the collar 1003 has a rotational position which is such that the tongue 1003a is in register with the outlet 1002a. As can be seen by consideration of Figure 7, if the collar 1003 is moved away from register with the inlet 1002a, the inlet 1002a lo will be progressively opened until the tongue 1003 moves completely out ofthe way of the inlet 1002a.

Generally speaking in pump units of the type considered in this application it is not necessary to obtain a perfect seal between components such as the tongue 1003a and the opening 1002a to the conduit 1002. If some water is able to leak out through such a path this is not of great concern. What is desirable is the ability to control, at a general level, the water flow which is occurring.

It can be seen that the conduit 1002 is defined partially by the side wall of the housing 1040b and partially by a component which is mounted to that side wall. The conduit extends in a generally axial direction relative to the upper portion 1030 and also extends generally axially relative to the W lamp 1080. The arrangement of the conduit 1002 is such that the water flow path passes the UV lamp in a first direction and then passes back along the conduit 1002 in an opposite direction before leaving via the take offoutlet 1001. It will be noted that in this embodiment a confined conduit 1002 is provided which extends around only a relatively small part of the circumference of the housing 1040 of the upper portion 1030. In an alternative, an annular conduit could be provided by providing a cylindrical wall portion which fits inside the housing 1040b and which has one or more suitable inlets at its upper end to allow the ingress of water.

Fountain by-pass outlets 1100 of the second pump unit 1000 can also be seen in Figure 7, and as in the first pump unit 10, water flow through these is controlled by the respective collar control 1102. Rotation of this collar control 1102 serves to alter the proportion of the by-pass outlets 1100 which are blocked to water flow.

The pump unit 1000 shown in Figures 6 and 7 also comprises a modified form of ball joint assembly 1004 which includes a ball joint 1034 which is the same as that in the pump unit of Figures 1 to 5 and which is again received in a socket 1032 in the upper portion 1030 of the unit. In this unit however, a W lamp obscuring disc 1004a is attached to the ball joint 1034 using a screw. This UV lamp obscuring disc 1004a serves to substantially prevent viewing of the UV lamp 1080 if the retaining collar 1036 is removed from the upper portion of the unit 1030. Furthermore, the inclusion of this obscuring disc 1004a also serves to capture the ball joint assembly 1004 in the upper portion of the unit. As can be best seen in Figure 6, the socket portion 1032 prevents movement of the ball joint assembly 1004 in one direction whereas the obscuring disc 1004a prevents movement of the assembly 1004 in the opposite direction. This means that not only does the obscuring disc 1004a blank out a possible line of sight to the W lamp 1080 when the retaining collar 1036 is removed but also prevents removal of the ball joint assembly 1004 from the external side of the casing 1 040b without first removing the obscuring disc 1 004a.

Whilst in this embodiment the obscuring disc 1004a is fixed to the ball joint 1034 using a screw, in alternatives the obscuring disc may be push fitted or clipped onto the ball joint 1034.

Claims

Claims 1. A pump unit for placing in a pond, the unit comprising a housing

in which is housed an electrical pump and an electrical W lamp, wherein the unit is arranged such that the pump can draw water from the pond and is operable to cause that water to flow past the W lamp, so as to be exposed to W light therefrom, before rejoining the pond.
2. A pump unit according to claim 1 which is arranged so that the pump unit is submersible in water.
3. A pump unit according to claim 1 or claim 2 in which the electrical components of the pump are contained in sealed container which is sealed against the ingress of water and the electrical components of the lamp are contained in sealed container which is sealed against the ingress of water.
4. A pump unit according to claim 3 arranged such that electrical components of the pump and of the W lamp are contained together in a sealed container in the housing, the sealing of the sealed container being against the ingress of water.
5. A pump unit according to claim 4 wherein all of the electrical components of the pump and the W lamp are contained in the container.
6. A pump unit according to claim 4 or claim 5 wherein the container is of one piece construction.
7. A pump unit according to claim 4 or claim 5 wherein the container is formed from separable components.
8. A pump unit according to any one of claims 4 to 7 wherein the sealed container is arranged to have a single power lead extending therefrom to supply electrical power to both of the pump and the lamp.
9. A pump unit according to any one of claims 4, 5, 7 and 8 wherein the sealed container is at least partly constituted by a removable cover for the W lamp, the cover being removable from the remainder of the sealed container.
10. A pump unit according to claim 9 wherein the cover is preferably at least partly of a material, such as quartz, that tends to allow W light to pass readily therethrough.
11. A pump unit according to claim 9 or claim 10 wherein the cover is a quartz tube, closed at one end and with a mounting structure at the other, open, end for sealedly and releasably mounting the cover to the remainder of the container.
12. A pump unit according to any preceding claim arranged such that the pump draws water from the pond past the W lamp and then into an inlet of the pump.
13. A pump unit according to any preceding claim arranged such that the pump draws water from the pond and pumps that water, from an outlet of the pump, past the W lamp.
14. A pump unit according to any one of claims I to 13 arranged such that the major dimension of the W lamp extends in the direction of water flow therepast. s
15. A pump unit according to any one of claims I to 14, arranged such that water flow past the lamp is substantially axial where the W lamp is tubular.
16. A pump unit according to any one of claims 1 to 15 arranged such that the water flow is all around the lamp in order to maximise exposure of the water to W light emitted by the lamp.
17. A pump unit according to any preceding claim, which further comprises a mechanical filtering means and is arranged such that the pump causes the water drawn from Me pond to pass through those means such that the water is filtered thereby.
18. A pump unit according to claim 17 wherein the filtering means comprises apertures formed in the housing of the unit and through which water from the pond is drawn by the pump.
19. A pump unit according to claim 17 or claim 18 wherein the filtering means include a filter member that is removably locatable in the housing.
20. A pump unit according to any one of claims 17 to 19 which further comprises a bypass for allowing water drawn from the pond to bypass at least part of the filtering means when water flow though that means is hindered by at least partial clogging thereof
21. A pump unit according to claim 20 wherein the bypass includes a valve.
22. A pump unit according to claim 21 wherein the valve is arranged such that at least partial clogging ofthe filter means increases a pressure difference across the valve such that the valve opens and allows water drawn from the pond to pass therethrough and to thereby bypass at least part of the filter means.
23. A pump unit according to claim 21 or claim 22 wherein a bypass member is provided that defines the bypass flow path with the valve situated therein.
24. A pump unit according to any of claims 21 to 23 wherein the valve comprises a thin flap of material that is resiliently biased in a closed position and is situated at an outlet side of the bypass flow path.
25. A pump unit according to claim 23 or claim 24 wherein the bypass member is arranged to receive the filter member such that the bypass flow path extends through the filter memba.
26. A pump unit according to any proceeding claim which further comprises biological filtering structure arranged with a high surface area to volume ratio and arranged in the housing such that water drawn from the pond is caused to flow over and around the structure.
27. A pump unit according to any preceding claim which further comprises a fountain outlet for creating a fountain.
28. A pump unit according to claim 27 which further comprises a bypass outlet arranged to provide an outlet for at least some of the water drawn from the pond, so as to bypass the fountain outlet and rejoin to the pond without forming a fountain.
29 A pump unit according to claim 28 in which the unit is arranged so that the bypass unit receives water that has already flowed past the W lamp.
30. A pump unit according to claim 28 or claim 29 which further comprises a variable flow control means to variably control the flow of water though the bypass outlet and/or the fountain.
31. A pump unit according to claim 30 wherein the variable flow control is arranged to be operable between a state in which flow through the bypass outlet is prevented and a state in which all water drawn from the pond is allowed to pass through the bypass outlet, and is operable at states therebetween.
32. A pump unit according to claim 30 or claim 31 in which the variable flow control is user adjustable by means of a rotatable collar.
33. A pump unit according to any one of claims 29 to 32 wherein the bypass outlet is positioned in the unit away from an inlet thereto through which water is drawn from the pond by the electrical pump.
34. A pump unit according to any one of claims 27 to 33 wherein the housing further comprises an outlet structure that at least partly defines the fountain outlet, the outlet structure being moveable relative to the remainder of the housing so as to allow water exiting the unit from the fountain outlet to be directed in a preferred direction.
35. A pump unit according to any preceding claim in which the unit comprises a takeoff outlet for supplying water via a hose to a remote outlet.
36. A pump unit according to claim 35 in which the unit comprises variable flow control means for variable control of water flow through the takeoff outlet.
37. A pump unit according to claim 36 in which the variable flow control means comprises a rotatable collar.
38. A pump unit according to any one of claims 35 to 37 in which the unit is arranged so that the takeoff outlet is positioned in the flow path so that water leaving via the takeoff outlet will have passed the W lamp.
39. A pump unit according to any one of claims 35 to 38 in which the unit comprises a takeoff outlet conduit providing a passage from the downstream end of the UV lamp to the takeoff outlet.
40. A pump unit according to claim 39 in which the takeoff outlet conduit comprises an inlet disposed at the downstream end of the W lamp.
41. A pump unit according to claim 40 when dependent on claim 36 in which the variable flow control means comprises a closure member for closing, by controllable degrees, the inlet of the takeoff outlet conduit.
42. A pump unit according to any one of claims 35 to 41 in which the takeoff outlet is disposed closer to a base of the unit than is the distal end of the W lamp.
43. A pond pump unit which comprises a housing in which is housed an electrical pump and a filter, wherein the unit is arranged such that the pump can draw water from the pond and is operable to cause that water to flow through the filter before rejoining the pond and wherein the unit includes a bypass for allowing water drawn from the pond to bypass the filter when water flow through the filter is hindered by at least partial clogging thereof
44. A pond pump unit according to claim 43 in which the bypass comprises a bypass member at least partially defining a bypass flow path and a flap of material that is resiliently biased in a closed position at an outlet side of the bypass flow path.
45. A pond pump unit which comprises a housing in which is housed an electrical pump wherein the unit is arranged such that the pump can draw wata from a pond and is operable to cause that wata to flow out of the housing via an outlet, the unit comprising variable flow control means for variably controlling flow of water from the outlet, the variable flow control means comprising a rotatable collar.
46. A pump unit according to claim 45 in which the rotatable collar surrounds a portion of the housing of the unit and is rotatable relative thereto.
47. A pond pump unit which comprises a housing in which is housed an electrical lo pump wherein the unit is arranged such that the pump can draw wata from the pond and is operable to cause that wata to flow out of the housing via a fountain outlet, the unit further comprising a bypass outlet arranged to provide an outlet for at least some of the wata drawn from the pond, so as to bypass the fountain outlet.
48. A pond pump unit according to any one of claims 43 to 47 which is arranged to be submersible in water.
49. A pump unit according to any preceding claim arranged with a base portion and a projecting upper portion upstanding therefrom.