The present disclosure relates to a press-type liquid pump, i.e. a dispenser pump for manual dispensing of product in fluid form out of a container and for leakproof assembly to an opening of the container by means of a closure and an elastic restoring means, such as a spring, for a dispenser pump. More specifically, the disclosure relates to a dispenser pump for manual dispensing of product in fluid form out of a container and for leakproof assembly to an opening of the container by means of a closure and a spring for a dispenser pump as defined in the introductory parts of independent claims.
There are many different types of known press-type liquid pumps on the market for dispensing liquid products, i.e. liquid soaps or the like. Such press-type liquid pumps are commonly installed at an opening of a container for pumping and dispensing the liquid product in the container out of the container by means of pressing operation manually performed by a user, often done by pressing downwards on a pump pressing head or the like. Such liquid pumps generally have at least one elastic restoring function or device for restoring its pump pressing head to an original position after the user has removed the downward pressing force on the pressing head, and during the restoring of the pressing head, thereby sucking the liquid product within the container into a liquid reservoir of the liquid pump for pumping and dispensing by a next pressing, this first action is commonly known as “priming”.
In prior art press-type liquid pumps, the elastic restoring function/device is commonly arranged between a movable unit, e.g. including the pressing head and a piston rod, and a fixed unit, e.g. including a cylinder, in a pre-loaded manner, ensuring sufficient elastic force to enable the movable unit to be returned to its original position relative to the fixed unit after the user has removed the downward pressing force.
An example of a press-type liquid pump is found in U.S. Pat. No. 9,539,597 B2 disclosing restoring means in the form of a leaf/plate spring.
Many prior art press-type liquid pumps use a metal spring for the restoring function. Any metal spring for use in such liquid pumps rusts easily due to damp/moisture and/or contact with liquid if made of a metal prone for this, and a rusted spring affects the product quality, i.e. including the quality of the spring and the liquid product in the container). Furthermore, the cost of a metal spring is relatively high, in particular if made of metal less prone to rusting. Regarding recycling of the liquid pump, a metal spring must be separated from other plastic members of the liquid pump for separate recovery increasing recycling cost or in reality even risks making recycling impossible.
Some problems with prior art solutions are that keeping the elastic restoring means in a loaded state for a long time would result in creeping and fatigue failure of the elastic restoring means, ultimately resulting in an insufficient rebounding force to restore a movable unit into its start or original position affecting the amount of liquid being dispensed/outputted by the liquid pump, and/or that a leaf/plate spring achieved by axially loading a beam, e.g. as in U.S. Pat. No. 9,539,597 B2, must have a pre-determined initial shape/deflection for ensuring a defined and controlled movement/bending when loaded and that such a leaf/plate spring provides an uncontrolled deflection if the pressing force exceeds the critical force/load of the spring, hence, if that occurs, the strain/stress in the spring becomes so high that the spring breaks or is plastic/permanent deformed and stops working as a spring, this behaviour is also affected by variation in the spring material, aging and/or too high or low surrounding temperatures, meaning that such an axially loaded beam for a spring is not robust enough and/or that a leaf/plate spring achieved by axially loading a beam, e.g. as in U.S. Pat. No. 9,539,597 B2, require larger effort, i.e. about 80% of the maximal pressing force applied by a user for bending the spring must be reached/used before a sufficient movement of the pump is induced, whereafter reaching this force only a small increase of the pressing force is required to achieve a large movement/displacement/deplacement and thereby a large dispensed amount of product meaning that correct dosage is difficult to achieve/control and also that spill/spillage is much more imminent/likely to occur, wherefore this type of leaf/plate spring is difficult to use and increases risk of faulty dosage and spill of product and/or that a leaf/plate spring achieved by axially loading a beam, e.g. as in U.S. Pat. No. 9,539,597 B2, require a large volume and surrounding space when deflecting/bending during use so that its deflection is not hindered by any obstacle in its direction of deflecting in the radial direction.
There is thus a need for improvement of manual press-type liquid pumps comprising elastic restoring functionality via a spring for restoring their moving and pumping parts.
It is an object of the present disclosure to mitigate, alleviate or eliminate one or more of the above identified deficiencies and disadvantages in the prior art and solve at least the above mentioned problem/-s.
According to a first aspect there is provided a dispenser/dispenser pump for manual dispensing of product in fluid form out of a container and for leakproof assembly to an opening of the container by means of a closure, the dispenser pump defining a longitudinal axis and comprising a housing adapted for being held fixed and/or stationary and/or axially in relation to the container after assembly, the housing defining a pump chamber with an inlet configured for fluid communication with the inside of the container, the dispenser pump comprising at least one spring, an actuator, a spout being configured for fluid communication with the inside of the pump chamber and a piston rod fixedly connected to the actuator and arranged for reciprocating motion inside the pump chamber, wherein the actuator is configured for moving together with its piston rod reciprocally relative the housing between a first/start position and an end and/or intermediary and/or activated position to pump product out of the container via the spout by use of a pressing force applied by a user to the actuator to move the actuator from its first or start position towards the housing and closure into its end and/or intermediary and/or activated position with its piston rod moving inside the pump chamber along the longitudinal dispenser pump axis and an elastic force of the spring to return the actuator with piston rod from the end or intermediary/activated position to the first position after the pressing force is removed for sucking in product into the pump chamber, wherein all parts of the dispenser pump are manufactured by recyclable plastic material including the spring having a helical shape, that the spring comprises a wire and a first end and a second end, wherein the wire is provided with a free wire end at each of the first and second end of the spring. An advantage is that simpler and faster recycling of a dispenser pump is provided. This is especially true if all parts of the dispenser pump is manufactured by recyclable plastic material within the same family of plastic, e.g. polyolefin. The spring is an elastic restoring device/means for the dispenser pump. An advantage of having a recyclable plastic spring with free wire ends is that strain/stress in the wire at the free ends is reduced. An advantage is that the helically shaped spring made of recyclable plastics material requires a smaller cross-sectional area compared to prior art while still providing the same spring characteristics. An advantage is that the helically shaped spring of recyclable plastics material requires less plastic material compared to prior art while still providing the same spring characteristics.
According to some embodiments, the spring is configured for arrangement at least partly outside or fully/wholly outside the container and/or the pump housing and/or the pump chamber and/or the piston rod. An advantage is that at least a part of the spring is not soiled by any product providing improved and prolonged functionality as the risk of jamming due to no or at least less buildup of product in the spring is eliminated. An externally arranged spring does not have to be introducible through a container opening, wherefore the spring may be provided with a larger size/diameter enabling optimising the cross-section of the spring, i.e. its wire size/cross-section for least spring volume possible versus optimal spring length. Furthermore, the plastics material of the spring does not have to be approved for food application and do not have to stand the product (e.g. acid or the like) as it does not physically contact the food product.
According to some embodiments, the spring is configured for being arranged at least partly or fully/wholly inside the container and/or the pump housing and/or the pump chamber and/or the piston rod. Advantages are that the spring is at least partly shielded from or at least somewhat protected from direct sunlight and/or oxygen by the container and/or product increasing the durability and/or life span of the spring by eliminating or at least reducing the degradation/decomposition/embrittlement of the plastic spring material and/or that the user of the dispenser pump does not risk getting caught, nipped or pinched by the spring when using the dispenser pump. An inner spring enable providing a dispenser pump of lower height/building height for smaller pump and/or dispensing volumes and the same design/look as prior art dispenser pumps with metal springs.
In some embodiments, the spring is configured for being arranged inside the container and the pump housing and the pump chamber. An inner spring enable providing a dispenser pump of lower height/building height and the same design/look as prior art dispenser pumps with metal springs.
In some embodiments, the spring is configured for being arranged at least partly inside the container and the pump housing and the pump chamber and the piston rod. An inner spring enable providing a dispenser pump of lower height/building height and the same design/look as prior art dispenser pumps with metal springs.
In some embodiments, the spring is configured for being arranged at least partly inside the container and the pump housing and configured for being arranged at least partly outside the pump chamber and the piston rod.
According to some embodiments, the pump chamber is configured for being located at least partly below the closure. According to some embodiments, the pump chamber is configured for being located fully/wholly below the closure. Advantages are that the spring is at least partly shielded from or at least somewhat protected from direct sunlight and/or oxygen by the container and/or product increasing the durability and/or life span of the spring by eliminating or at least reducing the degradation/decomposition/embrittlement of the plastic spring material and/or enable providing a dispenser pump for smaller pump/dispensing volumes with lower height/building height and the same design/look as prior art dispensers with metal springs. According to some embodiments, the pump chamber and the area/surfaces which the product is in contact with during pumping and dispensing and after filling the pump chamber are configured for being located fully/wholly below the closure.
According to some embodiments, the spring is relaxed when the actuator is in its first/start position before its first use and/or stroke. An advantage is that creeping and fatigue failure of the plastic material of the spring is eliminated or at least reduced.
According to some embodiments, the spring is under compression when the actuator has returned to its start position after its first use and/or stroke from the start position to the end/activated position and back to the first/start position, this first stroke being a first priming stroke for enabling filling the pump chamber with product. One or more strokes may be required as priming strokes for filling the dispenser pump fully including its pump chamber and all other surfaces/parts/areas that are configured for being in contact with the product after the full priming is achieved, e.g. the spout. An advantage is that the time during which the plastic spring is pre-loaded is reduced as the spring is stored without being preloaded before use, whereby the risk of creeping and fatigue failure of the plastic material of the spring is eliminated or at least the adverse effect of this is reduced during its operation, i.e. during its functional life span.
According to some embodiments, the spring is under compression when the actuator is in its first/start position before its first use and/or stroke. An advantage is that any priming is possible to perform/achieve quicker than hitherto possible with prior art pumps as the product is sucked in during the return stroke.
According to some embodiments, the spring is configured for being arranged at least partly between the container/pump housing/chamber/closure and the spout. Hence, the outer size/diameter of the spring is not limited, at least not fully limited, by the size of the opening of the container, i.e. the spring can be assembled at the opening of any container with a suitably adapted closure.
According to some embodiments, the spring is configured for being arranged fully/wholly between the container/pump housing/chamber/closure and the spout. Hence, the outer size/diameter of the spring is not limited by the size of the container opening, i.e. the spring can be assembled at the opening of any container with a suitably adapted closure.
According to some embodiments, the spring is configured for being arranged fully/wholly below the closure and/or spout. This provides an advantage in decreasing the height of the dispenser pump, i.e. its part being arranged outside the container and also enable the same design/size/height as for prior art dispenser pump meaning easy replacement of prior art dispensers without requiring more space.
According to some embodiments, the spring is configured for being arranged at least partly at/adjacent/close to/above the spout. This enables decreasing the building height of the dispenser pump and/or increasing the length of the spring when used for dispenser pumps with fixed nozzles/spouts.
According to some embodiments, the spring is configured for being arranged inside the container and/or pump housing and/or pump chamber at a distance from the closure. This provides a possibility of optimizing and improving the guiding of the piston rod movement in the pump chamber. This is improved by adapting the height of the closure of the container such that an upper part of guiding and a lower part of guiding the piston rod are separatated at sufficient distance from each other for increased stability when the piston rod reciprocates.
According to some embodiments, the dispenser comprises one or check valve made of a recyclable plastics material and configured for being arranged at the pump chamber inlet and a discharge valve made of a recyclable plastics material and configured for being arranged at the spout, the check valve is configured for being closed, when the user presses down on the actuator and moves the piston rod towards the pump chamber inlet compressing the spring while forcing product out of the pump chamber upwards towards the spout opening the discharge valve for dispensing product, and for being opened when the user releases the actuator/removes the pressing force by means of the spring returning the piston rod and actuator back into the first/start position while drawing out product inside the container into the pump chamber to fill it, while closing the discharge valve(s) and sealing or closing the pump chamber to prevent product from flowing back into the container once the pump chamber is filled. Hence, this provides a sufficient suction pressure when the piston rod returns to suck in product in the pump chamber from the container without risking sucking in air into the pump chamber through the spout opening.
According to some embodiments, the dispenser comprises a dip tube made of a recyclable plastics material and configured to extend from the inlet of the pump chamber with an adaptable length into a predetermined depth of the container depending on the type/size/length/height of the container. An advantage is that the dispenser is adaptable to containers of different lengths/depths. Another advantage is that this enables the dip tube to be as simple designed as possible, e.g. having a smooth in- and outside and be easily manufactured as piece or yard goods, i.e. by the metre, e.g. the rolled up on reels or coils, and then easily cut into desired lengths when to be used.
According to some embodiments, the free end of the dip tube configured for receiving product is cut into a predetermined shape and/or angle and/or size and/or diameter. If a dip tube is manufactured in a continuous way by the metre, a preferred cut angle is e.g. between 10° to 30° at each of its ends, whereby waste/loss of material is eliminated. An advantage is that an angled end guarantees that even though this angled dip tube end contacts the bottom of the container, this end is not closed off and product can still enter it. One advantage is that the inlet area of this angle cut end is larger compared to a straight cut end meaning a lower drop of pressure is achieved at the end being beneficial for viscous products.
In some embodiments, the actuator and the spout are configured to be movable together as one unit. This enables using the spout as a handle for pumping.
In some embodiments, the actuator is configured to be movable and the spout is stationary/fixated. This enables prolonging the spring and aligning the pressing force with the centre axis of the spring for better stability when pumping.
According to some embodiments, the spring is a twin spring. This provides a spring with longer stroke length than hitherto possible with prior art springs and enables an optimization of the cross-sections of the springs giving a minimum total spring volume/spring material consumption/use in a given space. In particular if combined with polygonal cross-sections for the wires of each spring.
In some embodiments, the dispenser pump comprises at least two springs. This gives at least the same advantages as for the twin spring disclosed.
In some embodiments, one spring is configured for being arranged inside another spring. This gives at least the same advantages as for the springs disclosed and a better/more efficient use of available space for the springs.
In some embodiments, a first spring has a size and/or diameter being adapted for fitting/being received within a second spring. This gives at least the same advantages as for the springs disclosed and optimised and more compact design for the springs.
In some embodiments, a first spring has a size being adapted for fitting/being received within a second spring, the springs having essentially same or the same length. This gives at least the same advantages as for the springs disclosed and more compact design, in particular in regard of the building height for the springs.
In some embodiments, a first spring is adapted for fitting/being received within a second spring, the springs being concentrically arranged. This gives at least the same advantages as for the springs as disclosed and an optimization of the spring functionality as any pressing forced applied to them is better aligned giving an increased stability.
In some embodiments, the centre axis of the first spring is aligned with the centre axis of the second spring. This gives at least the same advantages as for other embodiments as disclosed and further improved control of spring functionality/stability when compressed and relaxed.
According to a second aspect, a spring for a dispenser pump according to any preceding aspect/embodiment is provided, wherein the spring has a helical shape and is made of a recyclable plastics material and is at least partly shaped as a cylindrical and/or non-cylindrical helical spring. An advantage is that simpler and faster recycling of a spring and/or dispenser pump comprising such a spring is provided. This is especially true if all parts of the dispenser pump are manufactured by recyclable plastic material within the same family of plastic, e.g. polyolefin.
According to some embodiments, the spring comprises and/or is configured with and/or is configured for manufacture into a non-cylindrical shape being substantially symmetrical or symmetrical around its centre axis. An advantage is that if a certain function and/or design of a spring demand another shape for the spring this manufacture enables adapting the spring accordingly.
According to some embodiments, the spring comprises and/or is configured with and/or is configured for manufacture into the shape of a helically winded wire with a polygonal cross-section. This achieves a stronger/more durable spring when available space for it is limited compared to traditional circular cross-sections.
According to some embodiments, the spring comprises and/or is configured with and/or is configured for manufacture into the shape of a helically winded wire with a square cross-section. This gives at least the same advantages as for the springs disclosed above and/or below and further that the use/consumption of plastic material for making a spring is optimised and reduced.
According to some embodiments, the spring comprises and/or is configured with and/or is configured for manufacture into the shape of a helically winded wire with a rectangular cross-section. This gives at least the same advantages as for the springs disclosed above and/or below and that use/consumption of plastic material for making a spring is optimised and reduced.
According to some embodiments, the spring comprises and/or is configured with and/or is configured for manufacture into the shape of a helically winded wire with a quadratic cross-section. This gives at least the same advantages as for the springs as disclosed above and/or below and that the use/consumption of plastic material for making the spring is minimized.
According to some embodiments, the spring comprises and/or is configured with and/or is configured for manufacture into the shape of a helically winded wire with a triangular cross-section. This enables adapting the strength/durability of the spring when available space for it is limited compared to traditional circular cross-sections.
According to some embodiments, the spring comprises and/or is configured with and/or is configured for manufacture into the shape of a helically winded wire with a conical cross-section. This enables adapting the strength/durability of the spring when available space is limited compared to traditional circular cross-sections by orienting and arranging/locating the conical shape in an optimised way, e.g. directing its apex optimally.
According to some embodiments, the spring comprises and/or is configured with and/or is configured for manufacture into the shape of a helically winded wire with a rounded cross-section, such as an oval and/or elliptical cross-section.
According to some embodiments, the spring(s) comprise(s) and/or is/are configured with and/or is/are configured for manufacture into the shape of one or more helically winded wires with a combination of rounded cross-section(s), such as oval and/or elliptical cross-section(s), and non-rounded cross-section(s), such as polygonal and/or square and/or rectangular and/or quadratic and/or triangular and/or conical cross-section. This enables adapting the strength/durability of the spring when available space for it is limited compared to traditional cross-sections, e.g. when available space is limited in either the vertical direction, i.e. along the length of the spring in a substantially parallel direction or in a parallel direction or the horizontal direction, i.e. in the radial direction in an inclined direction relative the longitudinal spring extension or in a substantially perpendicular or perpendicular direction relative the longitudinal direction of the spring or in more than one direction corresponding to these directions or any other direction.
According to some embodiments, the spring comprises a conical spring wire cross-section being arranged with its apex directed radially outwards from the spring centre and/or longitudinal axis.
According to some embodiments, the spring comprises a conical spring wire cross-section being arranged with its apex directed radially inwards towards the spring centre and/or longitudinal axis.
According to some embodiments, the spring is configured with and/or for manufacture into the shape of a helically winded wire with a polygonal cross-section having a/an width/extension in the radial direction of the spring being less, equal or larger than its height/thickness/extension in the axial/longitudinal direction of the spring.
According to some embodiments, the spring being/when at least partly shaped as a conical helical spring, its apex is configured for facing towards the container bottom.
According to some embodiments, the spring being/when at least partly shaped as a conical helical spring, its apex is configured for facing towards the container opening.
According to some embodiments, the spring, being/when at least partly shaped as a conical helical spring, its apex is configured for facing towards the spout.
In some embodiments, the spring comprises and/or is configured for manufacture into and/or is configured with the shape of a helically winded wire with an oval and/or elliptical cross-section.
According to some embodiments, the spring comprises a first end and a second end, wherein at least one end is flattened and/or face grinded. Advantages are that its assembly is simplified as the flattening works as an end guidance and its stability is improved during its compression and relaxation as the spring is more steadily supported at its end by a larger supporting area/surface. This reduces the load/stress or even eliminates excess stress/load in at least parts of the first and last winding of spring wire having a lower cross-sectional height, so that these end windings are not overloaded limiting maximum capacity of the spring.
According to some embodiments, both its first end and second end are flattened/face grinded. Advantages are that assembly is simplified as the flattening works as ends guidance and stability is improved during compression and relaxation as the spring is more steadily supported at each end by totally larger supporting area/surface. This reduces the load/stress or even eliminates excess stress/load in at least parts of the first and last winding of spring wire having a lower cross-sectional height, so that these end windings are not overloaded limiting maximum capacity of the spring.
According to some embodiments, the end is flattened and/or face grinded in a plane being perpendicular to the centre/longitudinal axis of the spring. Advantages are that assembly is simplified as this flattening works as an end guidance and the stability of the spring is improved during compression and relaxation as the spring is more steadily supported at its end by a larger and more distinctly made supporting area/surface. This reduces the load/stress or even eliminates excess stress/load in at least parts of the first and last winding of spring wire having a lower cross-sectional height, so that these end windings are not overloaded limiting maximum capacity of the spring.
According to some embodiments, the spring is configured for manufacture by injection moulding and/or machining. An advantage is that simpler, quicker and cheaper manufacture of a spring is provided. This in particular being the case when a spring of recyclable plastics comprising and/or being configured with and/or for manufacture into the shape of a helically winded wire with a polygonal cross-section having a small angle of relief, e.g. about 1°-2°, as this simplifies manufacture by enabling providing the mould with a smooth centre axle and two mould halves that are able to move perpendicular to the centre axle of the mould and when the mould halves are opened the spring is easily removed from the mould. Such a polygonal shape of a spring wire cross-section is also of advantage when manufacturing such a spring of recyclable plastics by means of turning in a lathe or the like device.
In some embodiments, the spring is configured with a helical envelope surface formed by the outer surface of the helically winded wire, which windings form an at least partly open structure when the spring is relaxed.
In some embodiments, the spring comprises one or more open ends. In some embodiments, the spring comprises one or more open ends with one or more free spring wire ends.
In some embodiments, the spring comprises one or more closed ends. In some embodiments, the spring comprises one or more closed ends with one or more free spring wire ends.
In some embodiments, the spring comprises one or more closed and grounded ends. In some embodiments, the spring comprises one or more closed and grounded ends with one or more free spring wire ends.
In some embodiments, the spring comprises one or more double closed and grounded ends. In some embodiments, the spring comprises one or more double closed and grounded ends with one or more free spring wire ends.
In some embodiments, the housing of the dispenser pump is made of a recyclable plastics material. In some embodiments, the housing including the pump chamber with an inlet are made of a recyclable plastics material. In some embodiments, the actuator of the dispenser pump is made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator of the dispenser pump are made of a recyclable plastics material. In some embodiments, the spout of the dispenser pump is made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator and the spout of the dispenser pump are made of a recyclable plastics material. In an embodiment, the piston rod of the dispenser pump is made of a recyclable plastics material. In some embodiments, the closure of the dispenser pump for leakproof assembly to an opening of the container is made of a recyclable plastics material. In some embodiments, the closure of the dispenser pump for leakproof assembly to an opening of the container comprises one or more gaskets being made of a recyclable plastics material. In some embodiments, the closure of the dispenser pump for leakproof assembly to an opening of the container and its one or more gaskets are made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator and the spout and the piston rod of the dispenser pump are made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator and the spout and the piston rod and the spring of the dispenser pump are made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator and the spout and the piston rod and the spring and the closure of the dispenser pump are made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator and the spout and the piston rod and the spring and the closure and its gasket(s) of the dispenser pump are made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator and the spout and the piston rod and the spring and the closure and the dip tube of the dispenser pump are made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator and the spout and the piston rod and the spring and the check valve(s) of the dispenser pump are made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator and the spout and the piston rod and the spring and the closure and its gasket(s) and the check valve(s) and the dip tube(s) of the dispenser pump are made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator and the spout and the piston rod and the spring and the closure and its gasket(s) and the check valve(s) and the dip tube(s) and the discharge valve(s) of the dispenser pump are made of a recyclable plastics material. In some embodiments, the housing and its pump chamber with inlet and the actuator and the spout and the piston rod and the spring and the closure and its gasket(s) and the check valve(s) and the dip tube(s) of the dispenser pump are made of a recyclable plastics material, which dispenser pump is configured to be recycled with the container made of recyclable plastics material when assembled thereto or to be recycled separately when not assembled to the container. Effects and features of the second aspect are to large extent analogous to those described above in connection with the first aspect. Embodiments mentioned in relation to the first aspect are largely compatible with the second aspect.
The present disclosure will become apparent from the detailed description below. The detailed description and specific examples disclose preferred embodiments of the disclosure by way of illustration only. Those skilled in the art understand from guidance in the detailed description that changes and modifications may be made within the scope of the disclosure.
It is to be understood that the herein disclosed disclosure is not limited to the particular component parts of dispenser/spring/-s/described or steps of a method/-s described since such dispenser/spring/-s and method/-s may vary. It is also to be understood that the terminology used herein is for purpose of describing particular embodiments only, and is not intended to be limiting. It should be noted that, as used in the specification and the appended claim, the articles “a”, “an”, “the”, and “said” are intended to mean that there are one or more of the elements unless the context explicitly dictates otherwise. Thus, e.g., reference to “a unit” or “the unit” may include several devices, and the like. Further, the words “comprising”, “including”, “containing” and similar wordings does not exclude other elements or steps.
The above objects, as well as additional objects, features and advantages of the present disclosure will be more fully appreciated by reference to the following illustrative and non-limiting detailed description of example embodiments of the present disclosure, when taken in conjunction with the accompanying drawings.
The present disclosure will now be described with reference to the accompanying drawings/
In the cross-sectional views of
The first aspect of this disclosure shows the dispenser pump 10 that defines the longitudinal or centre axis CD. The dispenser pump 10 comprises a housing 20 adapted for being held fixed/stationary/axially in relation to the container 3 after assembly to the container by means of the closure 4. The housing defines an inner pump chamber 21 with an inlet 22 configured for fluid communication with the inside of the container and an outlet 23 configured for fluid communication with the outside of the container 3. The dispenser pump 10 comprises at least one spring 30 and a movable actuator 40. The dispenser pump 10 comprises a spout 41 configured for fluid communication with the inside of the pump chamber 21 via its outlet 23. In some embodiments, the spout 41 is preceded by one or more check valves 50 to facilitate the functionality of the spout when subjected to negative or suction pressure when product 2 is sucked in. The actuator 40 and the spout 41 is in one embodiment as shown on
After this first stroke performed by the user of the dispenser pump 10 and its actuator 40 as explained above down in the downwards direction visualized by the downward pointing arrow of the bidirectional arrow of
The spring 30 has in some or all embodiments a helical shape as shown in
As shown in the embodiments of
In some embodiments, such as in
The dispenser pump 10 comprises one or more check valves 50 made of a recyclable plastics material. The check valve 50 is shown in the shape of a rounded element, such as a sphere or ball in the embodiments of
In some embodiments, such as in
The second aspect of this disclosure shows in
In some embodiments of the first and/or second aspect of this disclosure, the spring 30 is configured with and/or for manufacture into a non-cylindrical shape being substantially symmetrical or symmetrical around its centre axis CS. The spring centre axis CS is shown in all figs. as substantially or perfectly aligned with the longitudinal axis CD of the whole dispenser pump 10, but, in some embodiments not shown, the axes CS and CD are not substantially or perfectly in alignment/parallel with each other, i.e. in some embodiments they extend in deviating directions and/or extend at an angle relative each other.
The spring 30 is in some embodiments configured with and/or for manufacture into the shape of a helically winded wire 33 with a polygonal cross-section 34 as seen in
The spring 30 is in some embodiments configured with and/or for manufacture into the shape of a helically winded wire 33 with a triangular cross-section 34 as shown in view IV of
In some embodiments as seen in views V and VI of
In some embodiments, the spring 30 is configured with and/or for manufacture into the shape of a helically winded wire 33 with a polygonal cross-section 34, see
In some embodiments, such as in view V of
According to some embodiments, the spring 30 when comprising and/or being configured with and/or for manufacture into the shape of a helically winded wire 33 with a conical cross-section 34 has a simplified manufacture, e.g. by enabling angle of clearance, see views V and VI of
In
In
In
In
The spring 30 comprises a first end 31 and a second end 32 as shown in
In
The cross-sections 34 shown in views V, VI, VII and VIII in
In
In some embodiments, the spring 30 is being configured for manufacture by injection moulding and/or machining.
In
In a further preferred aspect of the disclosure, the dispenser pump 10 has a locked condition in which the piston rod or plunger 42 and the button arrangement 43 are held axially fixed and hence non-operable. This locking action requires the button arrangement 43 and its face end or head 44 to be depressed and turned at the same time into a locking mode, whereafter any undesirable leakage or dribble of product 2 from the spout 41 and/or swinging spout/nozzle if not a fixated one. This locking also prevents any undesired leakage or dispensing when the dispenser pump 10 is transported with a container 3 or the like or when on display in a shop or the like full with product. The unlocking is done in a reversed manner.
In some or all embodiments, the guiding of the reciprocating movement of the piston rod 42 is optimised/improved by the adapting of the location and/or positioning and/or size/dimensions and/or diameter of the closure 4 and its surfaces through which and in contact with the piston rod 42 moves and a free end 42A of the piston rod. The other end of the piston rod 42 is arranged closer to the spout 41. This adaptation of the guiding surfaces and their separation is visualized by a guiding length or distance GL as shown to the right in
In
In some embodiments, see
The spring wire 33 comprises a first spring wire end 35 and a second spring wire end 36, see
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In some embodiments, the recyclable plastic material is within the same family of plastic, e.g. polyolefin. In some embodiments, the recyclable plastic material is Polyamide. In some embodiments, the recyclable plastic material is a combination or mixture of Polyamide and Polypropylene. In some embodiments, the recyclable plastic material is 100% Polyamide. In some embodiments, the recyclable plastic material is a combination or mixture of 90 to 98% of Polyamide (percentage by weight) and 2 to 10% of Polypropylene (percentage by weight). In some embodiments, the recyclable plastic material comprises up to 40% glass fibre (percentage by weight). In some embodiments, the recyclable plastic material is a combination of up to 40% glass fibre (percentage by weight) and other plastic material(s), such as Polyamide and/or Polypropylene according to any of the other embodiments. In some embodiments, the recyclable plastic material is a mixture of up to 40% glass fibre (percentage by weight) and other plastic material(s), such as Polyamide and/or Polypropylene or a combination of up to 40% glass fibre (percentage by weight) mixed with other plastic material(s), such as Polyamide and/or Polypropylene according to any of the other embodiments. In some embodiments, the recyclable plastic material comprises up to 40% glass fibre (percentage by weight) besides the amount of other plastic material(s), such as Polyamide and/or Polypropylene according to any of the above embodiments.
The person skilled in the art realizes that the present disclosure is not limited to the preferred embodiments described above. The person skilled in the art further realizes that modifications and variations are possible within the scope of the appended claims. For example, disclosed spring 30 is applicable for any dispenser pump having a moving spout 41 or fixated/stationary one. If the spring 30 is applied in a dispenser pump 10 with a fixed spout or nozzle 41, the dispensing of product 2 is achieved by leading the product along another path than shown in the disclosed figs. The twin spring 30 of
In some embodiments, the spring(s) 30 are configured such that they cannot be overloaded or overstressed, this being accomplished in that when the tension or stress in the plastic material(s) of the spring(s) 30 reaches about 60% or 60% of the yield point or yield strength for the plastics material(s), the spring(s) 30 bottom(s) meaning that the spring(s) is/are fully compressed such that all the spring wire windings of the wire 33 are in contact, i.e. closed, with no free space between them, and cannot be deformed more. This makes the spring 30 more robust and less prone for fatigue failure and/or creep strain/rupture.
Additionally, variations to the disclosed embodiments can be understood and effected by the skilled person in practicing the claimed disclosure, from a study of the drawings, the disclosure, and the appended claims. A free wire end 35, 36 of the wire 33 of the spring 30 means the end of the last coil or winding of the wire 33 at a spring end 31, 32 of the spring. This free wire end 35, 36 of the spring 30 is not hindered from moving. Hence, this free wire end 35, 36 and/or last coil/winding is not fixed or fixated or held stationary in relation to the previous coil or winding of the wire 33. In other words, the definition of free in “free wire end” 35, 36 is not defined as a wire end only being free from contact with any other coil or winding of the wire 33 as shown in the embodiments of
Number | Date | Country | Kind |
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1951415-7 | Dec 2019 | SE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/SE2020/051179 | 12/8/2020 | WO |