NO313409B1 - showerhead - Google Patents

Description

The present invention relates to a shower head comprising a nozzle with a central, axial, continuous channel for water flow, a rotationally symmetrical deflection element for the water being located near the outer mouth of the channel, which nozzle is in threaded connection with a holder through which the water is supplied and can be adjusted axially in relative to the holder, while the deflection element is held by a stem which with radial clearance projects axially into the channel, as well as being surrounded by a conical surface, the nozzle defining a cavity around and axially outside the deflection element, the conical surface projecting convergently outwards, and the stem is conical in the smallest in the part which is farthest from the deflection element, so that the surface of the stem converges towards the deflection element, and so that the flow cross-section for the water between the stem and the nozzle is changed by axial movement of the nozzle in relation to the holder.

Such a shower head is known from Norwegian patent no. 177256.

For many years, shower heads have been developed with the aim of low water consumption ("saving showers"), in the range of 6-10 l/min. This consumption is usually based on normal water pressure, which is approx. 300 - 500 kPa. As the water consumption is thus at "savings level" already at such normal pressures, lower pressure will mean that the consumption will be lower than desired. Water consumption is reduced to below the "comfort limit" and creates negative attitudes towards such shower heads.

Shower heads that can provide a pulsating shower have long been known. These are based on the use of a propeller-like rotor inside the shower head. Such shower heads can usually be switched between the normal condition for a steady water shower and the pulsating water shower.

Such shower heads are usually designed for high water consumption and they are complicated.

When developing shower heads for low water consumption, the aim has been rather unilaterally to achieve the low consumption, without the consequences in terms of effect, comfort and the structure of the water flowing out of the shower head having been taken into account. This has, on the one hand, in most cases resulted in low water speeds and an unfavorable water structure, and on the other hand constructions that can cause re-sealing due to impurities or lime in the water.

Norwegian patent no. 177256 describes a shower head that provides low water consumption at normal water pressure, which reduces water consumption at low water pressure to a lesser extent than known "saving showers", and which can also be switched between a normal state for showering and a state for pulsating showering ( "massage shower"), the latter condition being achieved without any rotating element in the shower head.

When the nozzle is screwed almost to the maximum into the holder, and consequently the deflection element is approximately at its greatest distance from the channel mouth, relatively large water droplets are formed with a relatively large mutual distance and high speed, and which leave the deflection element in a conical surface. Some of the water hits the wall of the cavity, and the water reflects off the wall and leaves the nozzle, forming a fairly homogeneous structure.

When the nozzle is screwed out further axially in relation to the holder, so that the deflection element is closer to the channel mouth, there will be an increased throttling at the deflection element, but this position is suitable for low water pressures, as a relatively greater water consumption and a water velocity is achieved that feels comfortable.

When the nozzle is screwed approximately to its end position from the holder, and the deflection element is consequently in maximum proximity to the nozzle, an instability will occur for the water, which flows out pulsating, i.e. the drops come out in "clusters".

The fact that the surface which surrounds the deflection element is mainly conical and converges outwards from the bottom surface of the nozzle is of importance for the flow of water around the deflection element.

The fact that the stem is conical has a direct effect on the water flow cross-section at the top of the channel. This cross-section will be smallest when the mouthpiece is screwed into the holder as far as it will go. At the same time, the deflection element is at its greatest distance from the mouth of the channel. Consequently, most of the throttling will take place at the top of the channel. The effect is the aforementioned relatively large water droplets. When, on the other hand, the nozzle is screwed out to the maximum in relation to the holder, this cross-section is at its largest. At the same time, the deflection element is at its smallest distance from the channel. Consequently, most of the throttling will take place at the deflection element. This enables an acceptable water speed and an acceptably high water consumption even at low pressures in the supplied water.

In the patent, the stem is shown screwed into a boss which is one with the holder through which the water is supplied. The water flows around the boss and along the trunk. It has been shown in practice that great accuracy should be maintained with regard to the alignment of the stem in the holder, according to which the deflection element on the free end of the stem should cooperate with the nozzle. A small angular error in the fixing of the stem in the boss could cause a significant incorrect location of the deflection element in relation to the nozzle, in that the deflection element becomes eccentric in relation to the nozzle. It is also desirable to be able to produce shower heads with mutually different characteristics with regard to water flow, but without having to make modifications to the holder or nozzle, which will usually be molded from plastic.

According to the present invention, a solution has been arrived at which simplifies and secures the alignment of the stem and which also enables the production of somewhat different shower heads, achieved with a very simple modification.

The invention is characterized by the fact that the stem is fixed in an insert part which is mounted in the holder, which insert part has at least one axially through opening to lead water to the channel.

The opening or each opening can be in the form of a groove in the outer surface of the insert part or a hole through the insert part.

The invention will be explained in more detail in the following, using an embodiment shown in the attached drawing.

The figure shows a shower head according to the invention, in a section axially through the center of the nozzle. The scale in the figure is approximately 1.5:1.

The section shown in the figure shows a channel 2' for water supply through a holder 2, only a part of which is shown closest to the shower head. It will be understood that the holder 2 can, in a known manner, be designed as a handle or be equipped with means to be attached to a wall holder, possibly as a combination of handle and fastening device.

The shower head comprises a nozzle 1, which is screwed into the holder 2 in threads 10. The threads are also used to regulate the axial position of the nozzle 1 in relation to the holder 2. A stop can be arranged to limit the possibility of such regulation. The figure shows ribs 15 on the nozzle 1, distributed around its circumference, to provide a good grip when screwing the nozzle 1 in relation to the holder 2.

The nozzle 1 has an inner cavity 9, which is open for water outflow, and which is approximately cylindrical in the inner part. Via an axial channel 8 and openings 17 in an insert part 16, the cavity 9 communicates with the inner channel 2' in the holder 2, via one or more holes 2"" in a boss 2"' in one with the holder 2.

In the example shown, a conical surface 7 is formed axially within the cavity 9 in the nozzle 1. The surface 7 may possibly be on a ring (not shown), which may be made of plastic, and which may be fixed in a press fit, but it is also possible to weld the ring, e.g. in ultrasonic welding, when nozzle 1 is also made of plastic. The ring can also be screwed into threads.

The holder 2 contains the insert part 16, which has a threaded bore 2" in the middle, and in the bore 2" is screwed an end 3' of a stem 3, the end 3' having threads 3". The insert part 16 is shown with axial, continuous grooves 17 in its outer surface, for the water. Instead of these grooves 17, the insert part 16 can have axial holes. The insert part 16 is mounted in the boss 2"' which is one with the holder 2. The insert part 16 is shown designed with an end pin 18, as for centering and stabilization is introduced in a hole 19 in the holder 2. At its outer end, in the cavity 9, the stem 3 holds an approximately disk-shaped deflection element 6, which on the axial side facing the channel 8 can be designed with a circumferential groove 6' around the end of stem 3 (shown dashed in the figure). Between the circumference of the deflection element 6 and the conical surface 7, there is an annular gap 4, which is changed by turning the nozzle 1 axially in relation to the holder 2. The stem 3 has a smaller diameter than the channel 8, so that water can flow in an annular space between the stem 3 and the wall of the channel 8. The axially outer surface 6" of the deflection element 6 is shown with a dome shape, but this surface is not believed to have any significant effect on the water flow.

Together with the deflection element 6, the surface 7 forms an annular chamber 7', which changes shape and size when the nozzle 1 is turned axially in relation to the holder 2, and the chamber 7' affects the water in different ways, depending on its shape and size.

The conical surface 7 need not be conical throughout its axial length. The surface 7 may be cylindrical or approximately cylindrical at the outer end, towards the cavity 9. The channel 8 may be mainly cylindrical, but closest to the chamber 7, the channel 8 may have a conical portion 8'.

The stem 3, at least in the area that is located in the innermost part of the channel 8 (closest to the insert part 16), is conical, so that the cross-section is largest towards the attached end 3' of the stem 3. When it is assumed that the channel 8 has a constant cross-section in this area, it is achieved that the flow cross-section for the water inside the channel 8 changes when the nozzle 1 is screwed axially in relation to the holder 2.

To produce shower heads with varying throttling, insert parts 16 can be produced with varying grooves or holes 17. The number of grooves or holes 17 can vary, the diameter of the holes, respectively the cross section of the grooves, can vary, the length of the insert part 16, and thus of the grooves or holes 17, may vary. Exclusively by producing different insert parts 16, shower heads with different properties with regard to the flow of water can thus be produced. The grooves or holes 17 cause a bottleneck before the water enters the channel 8.

The insert part 16 can be fixed in the holder 2 in many different ways. A simple way is to use a press fit. All insert parts 16 that are to be usable can have the same outer diameter, and the end pins 18 can be the same, so that the holder 2 does not need to be modified.

When the nozzle 1 is screwed approximately maximally into the holder 2, and the deflection element 6 is consequently approximately at its greatest distance from the outer mouth of the channel 8, relatively large water droplets are formed with a relatively large mutual distance and high speed, and which leave the deflection element 6 in a conic surface. Some of the water hits the wall of the cavity 9, and the water is reflected from the wall and leaves the nozzle 1, forming a fairly homogeneous structure.

When the nozzle 1 is screwed out further in relation to the holder 2, so that the deflection element 6 is closer to the channel mouth, there will be an increased throttling in the gap 4 at the deflection element 6. This position is suitable for low water pressures, as a relatively greater water consumption is achieved and a water speed that feels comfortable.

When the nozzle 1 is screwed approximately to its end position from the holder 2, and the deflection element 6 is consequently in maximum proximity to the nozzle 1, an instability will occur for the water, which flows out pulsatingly, and the shower feels like a massage.

The fact that the surface 7 which surrounds the deflection element 6 is mainly conical and converges outwards in the nozzle 1 affects the flow of water around the deflection element 6.

A sealing ring 12, shown as an O-ring, is mounted in an annular space between the holder 2 and the nozzle 1. The ring 12 prevents a drop in pressure due to leakage, and also prevents water from entering the cavity shown between the holder 2 and the nozzle 1 and creating unhygienic conditions, by water remaining in the cavity for a longer time.

It will be understood that the individual components in the shower head can consist of plastic or metal, with the exception of the O-ring 12, which can be made of synthetic rubber or natural rubber. The holder 2 and the nozzle 1 can e.g. is cast, while it is assumed most appropriate that the stem 3 and the deflection element 6 are produced in one piece, preferably of metal, e.g. brass, by mechanical processing, i.e. mainly turning and thread cutting.

The insert part 16 with the grooves or holes 17 can also be made of plastic. The grooves or holes 17 can be formed by casting, but the holes can also be drilled. The bore or hole 2" in the insert part 16 is preferably formed by casting, while the threads in the bore or hole 2" are formed by thread cutting or casting.

Claims (3)

1. Shower head comprising a nozzle (1) with a central, axial, continuous channel (8) for water flow, a rotationally symmetrical deflection element (6) for the water being located near the outer mouth of the channel, which nozzle (1) is in threaded connection with a holder (2) through which the water is supplied and can be adjusted axially in relation to the holder, while the deflection element (6) is held by a stem (3) which projects axially in the channel with radial clearance, and is surrounded by a conical surface (7), as the nozzle (1) delimits a cavity (9) around and axially outside the deflection element (6), the conical surface (7) projecting convergently outwards, and the stem (3) is conical at least in the part which is farthest from the deflection element (6 ), so that the surface of the stem (3) converges towards the deflection element (6), and so that the flow cross-section for the water between the stem (3) and the nozzle (1) is changed by axial movement of the nozzle (1) in relation to the holder (2), k a r acts in that the stem (3) is fixed in an insert part (16) which is mounted in the holder (2), which insert part (16) has at least one through opening (17) to lead water to the channel (8). 2. Shower head as stated in claim 1, characterized in that the insert part (16) has several parallel, axial grooves (17) distributed around the circumference. 3. Shower head as stated in claim 1, characterized in that the insert part (16) has several parallel, axial holes (17).