Patent Description:
Most conventional dental care units comprise a water system configured to provide water for various purposes during dental treatment. Generally, a tab water is being used when the water quality is such that it can be safely used in dental care units. If not, typically, reservoirs specifically configured for bottled water are used. To this end, water systems of typical dental care units comprise an upright bottle-shaped container with a bottom part, a tapered neck, and a mouth equipped with sealing and support mechanisms for connecting the container to the rest of the water system.

Usage of such bottle-shaped container necessitates utilization of an inlet tube, extending through the mouth and neck of the container to the bottom thereof, to enable utilization of at least most of the water stored in the container. However, such inlet tubes may prove difficult to clean and disinfect.

According to some known systems, disinfectant is poured into the water container and supplied into the water system with the water. The amount of disinfectant may be calculated or estimated before pouring it into the container. Before disinfection, the dental care unit must be taken out of use and the cover of the dental care unit needs to be opened. The water container is taken out of the dental care unit and the disinfectant is poured into the water container outside of the dental care unit. The pouring is messy and the amount of disinfectant entering the water container may be something else than intended.

Publication <CIT> discloses one disinfection system for handpieces of a dental surgery apparatus.

Considering the above, it may be desirable to develop new solutions related to dental care units and water disinfection systems thereof.

According to a first aspect, a disinfection system for a water system of a dental unit is provided. The water disinfection system comprises a vessel for receiving and holding liquids for the water system of the dental unit; a vessel holder for supporting the vessel inside the dental unit; and disinfectant container for storing disinfectant and a disinfectant supply line for supplying disinfectant from the disinfectant container into the vessel via the fluid duct. The system further comprises a weighing device for determining weight of any liquids in the vessel.

One of the advantages of embodiments of the system is that it is easier to clean and fill. The filling and refilling of the vessel and/or the disinfectant container may be done even during the operation, when the system is in use. Further, the amount of water and/disinfectant may be supplied automatically.

In an embodiment, the weighing device is arranged to measure the weight of the vessel holder, vessel and the liquid inside the vessel.

In an embodiment, the weighing device comprises a force-measuring scale arranged between the vessel holder and the dental unit.

In an embodiment, the system comprises pivoting means arranged to pivot the vessel holder about it, and the weighing device is arranged on the other side of the vessel than the pivoting means.

In an embodiment, the system comprises a disinfectant valve arranged to control the flow of disinfectant supplied into the vessel.

In an embodiment, the system comprises a water controlling valve arranged to control the flow of water supplied into the vessel.

In an embodiment, the system comprises a control unit for executing the disinfection process.

According to the invention, the control unit is configured to calculate the needed amount of disinfectant for achieving a pre-determined concentration of the disinfectant and the water in the vessel by calculating the needed amount of disinfectant based on the measurement data of the weighing device.

According to a second aspect, a dental care unit is provided. The dental care unit comprises a disinfection system in accordance with the first aspect.

According to a third aspect, a method for disinfecting the water system in accordance with the first aspect is provided. The method comprises steps of filling a vessel with an amount of water; weighing the water in the vessel; supplying an amount, based on the weight of the water, of disinfectant from the disinfectant container into the vessel; and supplying the concentration of the disinfectant and the water into the water system of the dental care unit.

The present disclosure will be better understood from the following Detailed Description read in light of the accompanying drawings, wherein:.

Unless specifically stated to the contrary, any drawing of the aforementioned drawings may be not drawn to scale such that any element in said drawing may be drawn with inaccurate proportions with respect to other elements in said drawing in order to emphasize certain structural aspects of the embodiment of said drawing.

Moreover, corresponding elements in the embodiments of any two drawings of the aforementioned drawings may be disproportionate to each other in said two drawings in order to emphasize certain structural aspects of the embodiments of said two drawings.

Concerning water systems and dental units discussed in this detailed description, the following shall be noted.

A "dental unit", or a "dental care unit", or a "dental treatment unit" may refer to a piece of equipment used in provision of dental care. A dental care unit may generally comprise any part(s) or element(s) necessary or beneficial for provision of dental care, e.g., a chair, a light source, one or more dental instruments, an instrument holder, and/or data input/output devices, such as a keyboard, a touchscreen, and/or a viewscreen. A dental unit may generally further comprise a water system.

In this specification, a "water system" may refer to a system for providing water for various purposes during use of a dental unit. Such uses may comprise, for example, feeding water through dental instruments for cooling e. cutting drill or rinsing chips from the surface of tooth being treated and/ or filling a cup for mouth rinsing. A water system may generally comprise any part(s) or element(s) necessary or beneficial for such provision of water, e.g., a water reservoir, such as a vessel; a water supply line for providing fresh water; one or more pumps; water lines; hoses; fittings; valves; a drainage system; a water purifier; and/or a cleaning device or arrangement for cleaning and disinfection of said water system or a part thereof.

<FIG> shows a partial cross-sectional view of a disinfection system for a water system of a dental care unit. Since <FIG> depicts a cross-sectional view of the disinfection system <NUM>, <FIG> does not limit shapes of the embodiment of <FIG> or any part(s) thereof in any direction forming an angle with the cross-sectional plane of <FIG>.

In this specification, a "vessel" may refer to a hollow container suitable for holding liquid, such as water. A vessel may or may not be (substantially) bowl-shaped and/or cup-shaped.

The disinfection system <NUM> of a dental unit may comprise a vessel <NUM> for receiving and holding liquids, such as water and disinfectant, for the water system of the dental unit, and a vessel holder <NUM> for holding the vessel inside the dental unit. The disinfectant <NUM> is stored in a disinfectant container <NUM>, from which the disinfectant is supplied into the vessel via a disinfectant supply line <NUM>. The disinfectant is supplied into the vessel via fluid duct <NUM>. Further, the disinfection system comprises a weighing device <NUM> for determining weight of any liquids in the vessel.

The disinfection container <NUM> may be located inside the dental unit so that the disinfectant <NUM> is supplied into the vessel via the disinfectant supply line <NUM> and the fluid duct <NUM> by the gravity, i.e. the disinfectant container is located above the vessel. A disinfectant control valve <NUM> may be provided within the disinfectant supply line <NUM> for controlling the supply of the disinfectant. The disinfectant control valve <NUM> may be for example a solenoid valve or any other valve which is suitable to control liquid supply.

The disinfection container <NUM> may be filled manually by the user but the supply of the disinfectant may be automated.

<FIG> shows another embodiment of the disinfection system. Only difference of the system of <FIG> and the system of <FIG> is that in the system of <FIG> disinfectant container <NUM> is pressurized. The disinfectant is supplied into the vessel via a disinfectant supply line <NUM> and the fluid duct <NUM> by adding a pressure inside the disinfectant container <NUM>. The system of <FIG> comprises a pressure control valve <NUM> for controlling the pressure inside the disinfectant container <NUM>. The disinfectant line may be partially directed upwards so that the disinfectant is not flown out of the disinfectant container <NUM> unintentionally by the gravity. Thus, there is no need for separate disinfectant control valve to control the supply of the disinfectant into the vessel.

The disinfection system <NUM> comprises a weighing device <NUM> for determining weight of any liquids possibly arranged in the vessel <NUM>. Such weighing device may enable determining, for example, automatically, a quantity of liquid(s) inside a vessel, even in the absence of sensor elements in said vessel. Additionally, or alternatively, such weighing device may facilitate disinfection of a water system by increasing precision of mixing ratios between water and disinfectant.

The weighing device may be configured to measure the weight of the vessel and the vessel holder, and set a zero-point based on these weights, i.e. calibrate to show only the weight of liquids in the vessel.

Throughout this specification, a "weighing device", may refer to any device for measuring a weight of an object. A weighing device may generally comprise any part(s) and/or element(s) suitable or necessary for measuring a weight of an object. A weighing device may comprise, for example, a balance scale and/or a force-measuring scale.

In one embodiment, the weighing device comprises a force-measuring scale <NUM> arranged between the vessel holder <NUM> and the dental unit, on which the vessel holder is arranged, for measuring the weight of the vessel holder, vessel, the insert and the liquid inside the vessel.

In one embodiment, the system may comprise a pivoting means <NUM>, such as joint, for pivoting the vessel holder about it. In an embodiment, the weighing device is arranged on the other side of the vessel than the pivoting means. However, the weighing device may be on the same side of the vessel as the pivoting means <NUM>.

The disinfectant system may comprise a water controlling valve <NUM> arranged to control the amount of water supplied into the vessel <NUM>.

The disinfection system comprises a control unit <NUM>. The control unit <NUM> may be configured to control operation of the disinfection system <NUM> and the water system <NUM> of a dental unit. The control unit <NUM> may be coupled to some or all of the valves of the systems so that it is configured to control the disinfectant valve <NUM>, water control valve <NUM> and/or pressure control valve <NUM>, i.e. the flows passing through the valves. The control unit <NUM> may be configured to execute the disinfection process, as described herein, so that the whole process may be executed without manual interaction.

The control unit <NUM> is coupled to the weighing device <NUM> to receive a signal from the weighing device <NUM>, which signal discloses the measurement data of the weight.

The control unit determines the needed amount of disinfectant, based on the measurement data of the weight. The control unit may transmit another signal to the disinfectant control valve <NUM> or the pressure control valve <NUM> to supply needed amount of disinfectant into to vessel to achieve pre-determined concentration of water and disinfectant for the disinfection process. The control unit may also control the control valves without the measurement data.

The control unit <NUM> may also be configured execute the circulation process of the disinfection liquid in the water system.

The control unit <NUM> is configured to receive a signal from the weighing device <NUM>, which signal discloses the measurement data. The control unit determines the needed amount of water, based on the measurement data of the weight, and transmits another signal to the water control valve <NUM> to supply needed amount of water into to vessel to achieve pre-determined amount of water and for the operation. The control unit may also control the water control valve without the measurement data.

The control unit <NUM> may be configured to open the water control valve <NUM>, when the weighing device recognizes that the water in the vessel is too low, i.e. the water system is configured to control the amount of water in the system and that the amount is enough for operation. This control may occur even during the operation.

The couplings between the control unit <NUM> and the other elements of the systems may be a wired coupling or wireless coupling, or it may comprise both wired and wireless elements either as alternatives of each other or augmenting each other.

If the water system <NUM> is not connected to the water line of a building, i.e. the water for the dental unit is provided with a separate means, e.g. by a bottle, the control unit <NUM> be arranged to alarm when the amount of water in the vessel is lower than pre-determined level. When the alarm is noticed, a user may fill the vessel from a bottle.

The control unit <NUM> may be installed inside the dental unit, or it may be installed outside of the dental unit.

In an embodiment, the control unit <NUM> is connected to a memory comprising a computer program comprising instructions which, when the program is executed by a computer, cause the computer to carry out the disinfection process and/or the water circulating process and embodiments of these described herein.

The control unit <NUM> may have a central role in the operation of the system. Structurally and functionally it may be based on one or more processors configured to execute machine-readable instructions stored in one or more memories that may comprise at least one of built-in memories or detachable memories.

shows an example of a water system of a dental care unit. The water system and parts of it, e.g. the vessel and the vessel holder, described herein may also be part of the disinfection system and, thus, the embodiments described herein may be applied to the disinfection system even when being described as embodiments of a water system.

<FIG> depicts a partial cross-sectional view of a water system <NUM> for a dental care unit according to an embodiment. Since <FIG> depicts a cross-sectional view of the water system <NUM>, <FIG> does not limit shapes of the embodiment of <FIG> or any part(s) thereof in any direction forming an angle with the cross-sectional plane of <FIG>.

The water system <NUM>, as described for example in <FIG>, comprises a vessel <NUM> comprising a bottom <NUM> and a side wall <NUM>. The side wall <NUM> extends from the bottom <NUM>. The side wall <NUM> has an inner surface <NUM>.

Herein, an "inner surface" of a side wall of a vessel may refer to a surface of said side wall configured to be in contact with a liquid, when the vessel is used for holding said liquid, or a part thereof.

The vessel <NUM> may further comprises a flange <NUM>, extending outward from the side wall <NUM> from an end thereof opposite to the bottom <NUM>. In some embodiments, a vessel may not comprise such flange.

The water system <NUM> comprises a vessel holder <NUM>, supporting the vessel <NUM>. As such, the water system <NUM> is depicted in <FIG> in an assembled state thereof.

In an embodiment, the vessel holder is a part of the vessel, i.e. the vessel and the vessel holder form a uniform part. It should be noted that any embodiment described herein may comprise uniform vessel and vessel holder, or separate vessel and vessel holder.

Herein, an "assembled state" may refer to a state of a water system wherein a vessel holder supports a vessel. On the other hand, a "disassembled state" may refer to a state of a water system wherein a vessel holder is at a distance from a vessel.

Further, the water system <NUM> comprises an insert <NUM> having a tubular wall structure <NUM>. The tubular wall structure <NUM>, as shown for example in <FIG>, has open ends <NUM>, <NUM>' and an exterior surface <NUM>.

Throughout this disclosure, the term "tubular" is to be interpreted broadly. As such, the term tubular may refer to any elongate and hollow shape, which may have any suitable cross-sectional shape. A tubular element may or may not have a circular, substantially circular, elliptical, or polygonal cross section. Additionally, or alternatively, a tubular element may or may not be tapered, cylindrical, and/or curvilinear. Consequently, a "tubular wall structure" may refer to at least part of an insert, having a tubular shape.

Throughout this disclosure, a "first open end" of a tubular wall structure may refer to a bottom end thereof configured for insertion in a vessel. Additionally, or alternatively, the first open end in the tubular wall structure may refer to said tubular wall structure defining an inner volume, accessible via said first open end. The tubular wall structure of the insert may also have at its top end a second open end.

In this specification, an "exterior surface" of a tubular wall structure may refer to a surface of said tubular wall structure configured to be arranged opposite an inner surface of a vessel in an assembled state of a water system, or a part thereof. Additionally, or alternatively, when a tubular wall structure defines an inner volume, an exterior surface of said tubular wall structure may refer to a surface of said tubular wall structure not connected with said inner volume, or a part thereof.

In <FIG>, the first open end <NUM> of the tubular wall structure <NUM> is arranged in the vessel <NUM> in such manner that a water conduit <NUM> is formed. The water conduit <NUM> of the embodiment of <FIG> extends from the first open end <NUM> of the tubular wall structure <NUM> and between the inner surface <NUM> of the side wall <NUM> and the exterior surface <NUM> of the tubular wall structure <NUM>. Generally, arranging a vessel and an insert in such manner that such water conduit is formed may enable utilization of a significant portion of water in the vessel, even in the absence of tubing extending upstream of the vessel. Additionally or alternatively, such arrangement of a vessel and an insert may facilitate filling, cleaning, and/or disinfection, especially while there is no tubing extending in a water reservoir.

Herein, a "water conduit" may refer to a channel, passage, or duct for transporting a fluid, such as a liquid, e.g., water.

The exterior surface <NUM> may be complementarily shaped with the inner surface <NUM> of the side wall <NUM> such that the first open end <NUM> of the tubular wall structure <NUM> may be arranged in the vessel <NUM>, as depicted in <FIG>. In embodiments, the exterior surface of the tubular wall structure may be shaped, for example, complementarily, with the inner surface of the side wall of the vessel, enabling arrangement of the first open end of said tubular wall structure in said vessel in an assembled state.

Herein, an exterior surface being "complementarily shaped" with an inner surface may refer to said surfaces being arrangeable so as to form a technically relevant arrangement or element.

The inner surface <NUM> may have a frustoconical shape. Generally, an inner surface of a side wall may have any suitable shape. In some embodiments, an inner surface of a side wall may have a cylindrical, or conical, or truncated conical, or pyramidal, or truncated pyramidal, or frustal, or frustoconical shape. Such shapes may generally facilitate arranging an insert into a vessel.

Additionally, or alternatively, such shapes may facilitate cleaning a water system by improving access to an inner surface and/or a bottom of a vessel.

The water conduit <NUM> may have a thickness t of <NUM>-<NUM>, for example. Generally, a higher thickness of a water conduit may facilitate usage of higher mass and/or volumetric flow rates in a water system. In embodiments, a water conduit may have any suitable thickness. In some embodiments, a water conduit may have a thickness of <NUM>,<NUM>-<NUM>, or at least <NUM>, or at most <NUM>, or at most <NUM>, or at most <NUM>.

Herein, a "thickness" of a water conduit may refer to a transverse dimension of said water conduit. A thickness of a water conduit may generally be measured perpendicular to an inner surface of a side wall and/or perpendicular to an exterior surface of a tubular wall structure, i.e. minimum distance between the inner surface of a side wall and exterior surface of the tubular wall structure.

A shown for example in <FIG>, the tubular wall structure <NUM> may be removable from the vessel <NUM> in the disassembled state. A tubular wall structure of an insert being removable from a vessel may facilitate cleaning and/or disinfecting said insert and/or said vessel. Additionally, or alternatively, a tubular wall structure of an insert being removable from a vessel may facilitate usage of automated cleaning tools, such as a dishwasher, for purification of said insert and/or said vessel. In embodiments, a tubular wall structure of an insert may be removable from a vessel in a disassembled state.

In <FIG>, the vessel <NUM> has an (imaginary) center line <NUM>, extending through the first open end <NUM> of the tubular wall structure <NUM>.

Herein, a "center line" may refer to any suitable (imaginary" line. A center line may or may not extend through center point(s), such as a center of mass and/or a centroid, of a vessel. A center line may or may not extend along a symmetry axis and/or a symmetry plane of a vessel. A center line may or may not be arranged (substantially) vertically in an assembled state.

Any transverse distance DT(z), measured perpendicular to and from the center line <NUM> to the inner surface <NUM> along a constant azimuthal direction, is non-decreasing with increasing axial distance z from the top surface <NUM>. Such shape of a vessel may generally facilitate insertion of an insert into said vessel and/or removal of an insert from said vessel. In embodiments, a vessel may or may not be shaped in such manner.

In a cross section of the water system <NUM>, as shown for example in <FIG>, perpendicular to the center line <NUM>, the water conduit <NUM> may form a continuous loop surrounding the exterior surface <NUM> of the tubular wall structure <NUM>. Such cross-sectional shape of a water conduit may facilitate usage of higher mass and/or volumetric flow rates in a water system. In embodiments, in a cross section of a water system perpendicular to a center line, a water conduit may or may not form a continuous loop surrounding an exterior surface of a tubular wall structure.

The bottom <NUM> has a top surface <NUM>, which may be outlined by the inner surface <NUM> of the side wall <NUM>. Generally, a bottom may have such top surface.

The top surface <NUM> may be continuous, as shown for example in <FIG>. In embodiments, a top surface of a bottom may or may not be continuous. For example, in some embodiments, a bottom may comprise an extrusion with a through-hole, the extrusion extending through an open end of a tubular wall structure in an assembled state.

In <FIG>, a maximum height difference Δhmax between the first open end <NUM> of the tubular wall structure <NUM> and the top surface <NUM> of the bottom <NUM> may be, for example, <NUM> millimeters (mm). In embodiments, any suitable maximum height difference may exist between the first open end and a top surface. In some embodiments, a maximum height difference less than or equal to <NUM>, or less than or equal to <NUM>, or less than or equal to <NUM>, or less than or equal to <NUM> may be utilized, for example. A lower maximum height difference may generally enable utilization of a higher portion of water storable in a water system.

The vessel holder <NUM> may comprise a through-hole <NUM>, as shown for example in <FIG>. The vessel <NUM> is configured to be arranged in the through-hole <NUM> in the assembled state of the water system <NUM>. To this end, in the assembled state of the water system <NUM>, the flange <NUM> of the vessel <NUM> is coupled with the vessel holder <NUM>, and the side wall <NUM> of the vessel <NUM> extends through the through-hole <NUM>. Such arrangement of a vessel in a through-hole of a vessel holder may generally facilitate forming a fluid-tight coupling between said vessel and said vessel holder.

In embodiments, a vessel may be configured to be arranged in a through-hole of a vessel holder in an assembled state of the water system. In embodiments, wherein a vessel is configured in such manner, said vessel may or may not comprise a flange. For example, in some embodiments, a side wall of a vessel may be coupled with vessel holder in the absence of any flange in said vessel.

As depicted in <FIG>, the insert <NUM> may be supported by the vessel <NUM> in the assembled state of the water system <NUM>. Such arrangement may generally facilitate forming a water conduit between an inner surface of a side wall and an exterior surface of a tubular wall structure. In embodiments, an insert may or may not be supported by a vessel in an assembled state of a water system. Generally, an insert may be supported by any suitable means in an assembled state of a water system. For example, in some embodiments, wherein a water system comprises a frame and/or a vessel holder, an insert may be supported by said frame and/or said vessel holder.

The insert <NUM> may comprise a projecting part <NUM>, such as flange, extending from the tubular wall structure <NUM>. In embodiments, an insert may or may not comprise such projecting part.

The projecting part <NUM> may comprise a plurality of depressions, each depression <NUM> of the plurality of depressions providing a supporting surface <NUM>. In embodiments, a projecting part may or may not comprise a support element, such as a depression or a protrusion, for providing a supporting surface.

The supporting surfaces <NUM> may be configured to be connected with the flange <NUM> of the vessel <NUM> in the assembled state of the water system <NUM>, as shown for example in <FIG>. In embodiments, a supporting surface may or may not be configured to be connected with a vessel, e.g., a flange thereof, in an assembled state of a water system. In some embodiments, an insert may comprise a support element, such as a depression or a protrusion, in the absence of a projecting part and/or a vessel may comprise a support element for supporting an insert. Generally, a plurality, i.e., two or more, three or more, etc., of support elements may be used. In some embodiments, a separate support element, such as perforated ring, may be arranged between a vessel and an insert.

In the embodiment, as shown for example in <FIG>, the vessel <NUM> and the insert <NUM> may be formed of a plastic material. Such material choice may facilitate usage of high-throughput fabrication methods in manufacturing of a vessel and/or an insert. Additionally, or alternatively, usage of plastic materials may reduce corrosion-related effects, when a vessel and/or an insert is subjected to cleaning agents. In embodiments, a vessel and/or an insert may comprise or be formed of any suitable material(s), such as plastics, metals, and/or ceramics.

In <FIG>, the water system <NUM> comprises a lid <NUM>. The lid <NUM> has a top surface <NUM>, facing upwards in the assembled state of the water system <NUM>. The lid <NUM> is configured to couple with, more specifically rest on and be supported by, the insert <NUM> in the assembled state of the water system <NUM>. In said other embodiments, said lid may or may not be configured to couple with, e.g., rest on and/or be supported by, an insert in an assembled state.

The lid <NUM>, as shown for example in <FIG>, may comprise a fluid duct <NUM>. The fluid duct <NUM> is configured to provide a fluid communication path between the water conduit <NUM> and ambient environment in the assembled state of the water system <NUM>. Generally, a lid with such fluid duct may facilitate provision of replacement air into a vessel, when a water system is used. Provision of replacement air may, in turn, simplify an overall design of a water system and/or reduce manufacturing constraints thereof.

Throughout this specification, "ambient environment" may refer to any surroundings of a dental unit and/or a water system thereof. Additionally, or alternatively, an ambient environment may refer to ambient gas, such as ambient air and/or gas atmosphere, surrounding a dental unit and/or a water system thereof.

Regardless whether or not a lid is arranged to the water system, the second open end <NUM>' of the insert is preferably in connection with the ambient environment.

In the embodiment, the water system <NUM> may comprise a fluid-tight first seal <NUM> joining the insert <NUM> with the lid <NUM>, a fluid-tight second seal <NUM> joining the lid <NUM> and the vessel holder <NUM>, and/or a fluid-tight third seal <NUM> joining the vessel holder <NUM> with the vessel <NUM>. In embodiments, a water system may or may not comprise such first seal, such second seal, and/or such third seal.

In embodiments wherein the vessel and the vessel holder form a uniform part, there is no need for third seal <NUM> for joining the vessel holder with the vessel.

In this specification, a "seal" may refer to any part, element, or structure suitable for providing a fluid-tight, e.g., liquid-tight, such as water-tight, and/or gas-tight, such as air-tight, coupling between a first object and a second object coupled with the first object. A seal may join such first object with such second object. Additionally, or alternatively, such second object may be coupled with such first object via a seal. A seal may comprise any suitable element(s) for provision of such fluid-tight coupling, for example, a gasket, such as an O-ring, or a sealant, or the like.

Since the water system <NUM> of the embodiment of <FIG> comprises the first seal <NUM>, the second seal <NUM>, and the third seal <NUM>, a collection space <NUM> is defined. The water conduit <NUM> extends from the open end <NUM> of the tubular wall structure <NUM> to the collection space <NUM> between the inner surface <NUM> of the side wall <NUM> and the exterior surface <NUM> of the tubular wall structure <NUM> to the collection space <NUM>. As such, the water conduit <NUM> may transport water towards the collection space <NUM> from the vessel <NUM>, when the water system <NUM> is used. Such collection space may generally simplify a structure of a water system. Additionally, or alternatively, such collection space may facilitate usage of more rigid parts and/or elements in a water system, which may, in turn, facilitate mechanical and/or automated cleaning of said water system. In other embodiments, a water system may not comprise such collection space.

The collection space <NUM>, as shown for example in <FIG>, is in fluid communication with the ambient environment via the water conduit <NUM> and the fluid duct <NUM>. In embodiments, wherein a collection space is defined due to a water system comprising a first seal, a second seal, and/or a third seal, said collection space may or may not be fluid communication with an ambient environment via a water conduit and a fluid duct of a lid.

The water system <NUM> may further comprise a pump <NUM>, which may be arranged upstream of the collection space <NUM>. The pump <NUM> may be used to effect fluid flow, e.g., water flow, in the water conduit <NUM>. Such arrangement of a pump may, for example, increase fluid-tightness of a first seal, a second seal, and/or a third seal. In embodiments, a water system may or may not comprise such pump. In embodiments, wherein a pump is arranged upstream of the water conduit for effecting fluid flow therein, any suitable type of pump, for example, a positive displacement pump, may be used.

As shown for example in <FIG>, the water system <NUM> may further comprise a water delivery line <NUM>. The water delivery line <NUM> provides a fluid communication path after the collection space <NUM> and/or the pump <NUM>. The water delivery line may comprise a water control valve <NUM> arranged to control the amount of water supplied into the vessel.

Herein, a "water delivery line" may refer to a fluid flow line configured to distribute water from a water reservoir of a water system within said water system. A water delivery line may be configured, for example, to supply water via dental instruments into a patient's mouth and/or via a tap to a cup, when a water system is used. In embodiments, a water system may or may not comprise a water delivery line. In embodiments, wherein a water system comprises a water delivery line, a water delivery line may or may not be in fluid communication with a collection space.

As shown for example in <FIG>, the water system <NUM> may further comprise a water supply line <NUM>. In embodiments, a water system may or may not comprise a water supply line. For example, in some embodiments, a water system may be supplied with water manually.

The water supply line <NUM> may be configured to supply water, e.g., tap water from a public tap water network, into the vessel <NUM> via the fluid duct <NUM> of the lid <NUM>, whenever required. Such fluid duct may generally facilitate provision of water into a vessel, when a water system is used. In embodiments, a water system may or may not comprise a water supply line configured in such manner.

The water supply line <NUM> may have a supply line end <NUM>. In the assembled state of the water system <NUM>, the supply line end <NUM> is arranged above the fluid duct <NUM> of the lid <NUM>. In the assembled state, a minimum height difference Δhmin between the top surface <NUM> of the lid <NUM> and the supply line end <NUM> may be, for example, <NUM>, <NUM>, <NUM>, <NUM>, or <NUM>. Generally, a higher minimum height difference between a top surface and a supply line end may facilitate preventing backflow of water from a vessel into a water supply line, when a water system is used. Protection against pollution of potable water and backflow prevention are discussed, for example, in standard BS EN <NUM>. In embodiments, any suitable minimum height differences may be used. In some embodiments, a minimum height difference between a top surface and a supply line end in an assembled state of a water system may be at least <NUM>, or at least <NUM>.

<FIG> depicts schematically a dental care unit <NUM> according to an embodiment. The embodiment of <FIG> may be in accordance with any of the embodiments disclosed with reference to, in conjunction with, and/or concomitantly with <FIG>. Additionally, or alternatively, although not explicitly shown in <FIG>, the embodiment of <FIG> or any part thereof may generally comprise any features and/or elements of any of the embodiment of <FIG>.

The dental care unit <NUM> comprises a water system <NUM>. The water system <NUM> comprises a vessel <NUM> and an insert <NUM>. The vessel <NUM> and the insert <NUM> may be arranged inside or outside of a housing or the like. The water system <NUM> further comprises a vessel holder <NUM>.

In operation, disinfecting is carried out by the following steps:
The vessel is filled with an amount of water, which amount may be defined by the user. The water in the vessel is weighed by the weighing device and an amount, based on the weight of the water, of disinfectant from the disinfectant container into the vessel. The concentration of the disinfectant and the water is supplied into the water system of the dental unit. Further, the concentration of the disinfectant and the water may be removed from the water system and fresh water is supplied into the vessel. The fresh water may be used to rinse the water system to ensure that the disinfectant is removed from water system and the dental unit is ready to operate. All of the above steps or some of the steps may be executed automatically or manually.

Example embodiments may be implemented in software, hardware, application logic or a combination of software, hardware and application logic. The example embodiments can store information relating to various methods described herein. This information can be stored in one or more memories, such as a hard disk, optical disk, magneto-optical disk, RAM, and the like. One or more databases can store the information used to implement the example embodiments. The databases can be organized using data structures (e.g., records, tables, arrays, fields, graphs, trees, lists, and the like) included in one or more memories or storage devices listed herein. The methods described with respect to the example embodiments can include appropriate data structures for storing data collected and/or generated by the methods of the devices and subsystems of the example embodiments in one or more databases.

The components of the example embodiments may include computer readable medium or memories for holding instructions programmed according to the teachings and for holding data structures, tables, records, and/or other data described herein. In the context of this document, a "computer-readable medium" may be any media or means that can contain, store, communicate, propagate or transport the instructions for use by or in connection with an instruction execution system, apparatus, or device, such as a computer. A computer-readable medium may include a computer-readable storage medium that may be any media or means that can contain or store the instructions for use by or in connection with an instruction execution system, apparatus, or device, such as a computer. A computer readable medium can include any suitable medium that participates in providing instructions to a processor for execution. Such a medium can take many forms, including but not limited to, non-volatile media, volatile media, transmission media, and the like.

It is obvious to a person skilled in the art that with the advancement of technology, the basic idea of the invention may be implemented in various ways. The invention and its embodiments are thus not limited to the examples described above, instead they may vary within the scope of the claims.

It will be understood that any benefits and advantages described above may relate to one embodiment or may relate to several embodiments.

Claim 1:
A disinfection system for a water system of a dental care unit, the disinfection system (<NUM>) comprising:
- a vessel (<NUM>) for receiving and holding liquids for the water system of the dental care unit;
- a vessel holder (<NUM>) for supporting the vessel inside the dental care unit; and
- disinfectant container (<NUM>) for storing disinfectant and a disinfectant supply line (<NUM>) for supplying disinfectant from the disinfectant container (<NUM>) into the vessel (<NUM>) via a fluid duct (<NUM>);
characterized in that the system comprises a weighing device (<NUM>) for determining weight of any liquids in the vessel (<NUM>) and a control unit (<NUM>), which is configured to calculate the needed amount of disinfectant for achieving a pre-determined concentration of the disinfectant and the water in the vessel (<NUM>) by calculating the needed amount of disinfectant based on the measurement data of the weighing device (<NUM>).