The present disclosure relates to a menstrual cup adapted for the collection of menstrual fluids and methods for the manufacturing and use thereof.
In the current society, consumers are increasingly aware of the environmental effects of their purchases. This often results in a feeling of guilt when purchasing products having a short usage time, such as a couple of hours, made from materials originating from finite sources such as disposable articles. Such feelings are often referred to as “consumer guilt”.
Menstrual cups having a longer usage time can partly relief this consumer guilt. Such menstrual cups have previously been known in the art by, for example, international patent application No. PCT/CA2005/001443.
However, many menstrual cups produced today are manufactured from organosilicon oxide polymers wherein the hydrocarbons originate from non-renewable resources such as petroleum or natural gas. In addition to the limited supply of petroleum and natural gas, the methods for obtaining and processing these materials have a negative impact on the environment.
Therefore, there is an increased need for the development of menstrual cups manufactured from materials with an improved environmental impact.
The present disclosure is based on the need for menstrual cups manufactured from materials with an improved environmental impact. The present disclosure provides a menstrual cup comprising a renewable thermoplastic elastomer.
At least one of the objectives is achieved by, or at least partly achieved by, a menstrual cup comprising a receptacle. The receptacle has an exterior surface and an interior surface, with the interior surface defining at least in part an interior cavity adapted for collecting fluid. The receptacle extends from an open top end to a closed bottom end, wherein the open top end has a predetermined diameter. The receptacle further comprises an upper rim portion at the open top end of the receptacle, and a main portion defining a decreasing diameter of the interior cavity while extending downwards from the open top end to the closed bottom end of the receptacle. Furthermore, the receptacle is at least partly formed of a renewable thermoplastic elastomer.
Thermoplastic elastomers have high elastomeric properties giving the menstrual cup the required flexibility to assume different configurations for easy inserting and removing of the menstrual cup, and to return to its original configuration during use. Furthermore, thermoplastic elastomers are easy to use in manufacturing, especially in injection molding processing. Due to their thermoplastic properties, thermoplastic elastomers can undergo several cycles of molding, extrusion and use and can thus be recycled. This is in contrast to rubbers which are in general not recyclable due to their thermosetting characteristics.
The use of a renewable thermoplastic elastomer in the manufacturing of the menstrual cup reduces the environmental impact of the menstrual cup manufacturing process. Further, the use of a renewable thermoplastic elastomer for the manufacturing of the menstrual cup may partly relief consumer guilt when discarding the menstrual cup.
The thermoplastic elastomeric material may be selected from the thermoplastic polyurethane elastomers and/or thermoplastic styrene elastomers. Thermoplastic polyurethane elastomers have a higher Shore A value than thermoplastic styrene elastomers. However, thermoplastic styrene elastomers have a lower tear strength than thermoplastic polyurethane elastomers.
The renewable thermoplastic elastomer may be present at about 20-100% by weight of the total weight of the thermoplastic elastomer.
The renewable thermoplastic elastomer may be present at about 30-90% by weight of the total weight of the thermoplastic elastomer.
The renewable thermoplastic elastomer may be present at about 40-80% by weight of the total weight of the thermoplastic elastomer.
The renewable thermoplastic elastomer may be present at about 50-70% by weight of the total weight of the thermoplastic elastomer.
The renewable polymer in the present disclosure may not be biodegradable as biodegradable polymers have hydrophilic properties which may hinder effective containment of the menstrual fluid in the receptacle.
The main portion of the menstrual cup may have a shore hardness between Shore A 20 and Shore A 70 to provide sufficient flexibility and resiliency for the menstrual cup to assume different configurations pre-use, during insertion/removal and during use.
The menstrual cup may be a one-period cup. By the term “one-period cup” as used herein, is meant a cup that can be discarded after one menstrual period while at the same time having a limited negative impact on the environment due to the presence of renewable polymers in the menstrual cup. This may also lead to a reduced feeling of “consumer guilt”. By reducing the usage time of the menstrual cup to one menstrual period, there may be a reduced requirement for cleaning and sterilization.
An array of menstrual cups may be provided both in respect of receptacle dimension and Shore A hardness of the material. Thus, an array may be provided wherein the receptacle has at least two different dimensions such that the first dimension has the capacity to receive a larger amount of fluid than the second dimension. By providing menstrual cups with different dimensions, menstrual cups can be provided to users with different vaginal anatomies. For example, a menstrual cup of a smaller size might be a better fit for women having a low cervix and thus shorter vaginal canal. Conversely, a menstrual cup having a bigger size might be a better fit for women having a high cervix and thus longer vaginal canal. Furthermore, an array of menstrual cups may be provided wherein the receptacle has at least two different dimensions such that the first dimension is adapted for uses that have not given birth vaginally and a second dimension adapted for users that have given birth vaginally. As childbirth is often accompanied by physical modification in the vaginal channel, it may be beneficial to adapt the menstrual cup to these physical modifications by e.g. changing the dimension of the receptacle. Further, an array of menstrual cups may be provided wherein the material constituting the receptacle has at least two Shore A values depending on the user preferences. In general, softer menstrual cups are more comfortable during use as they apply less outward pressure against the vaginal wall. On the other hand, softer menstrual cups require more manual manipulation to get them to open inside the vagina. Further, use of harder menstrual cups may be recommended during exercise as these cups will be less prone to being pushed out by the muscles in the vaginal canal.
By providing the receptacles of varying dimensions and/or material hardness as an array, it is clear to the user that the menstrual cups are produced by the same manufacturer, and therefore the same quality level is to be expected.
The present disclosure also pertains to a method for manufacturing a menstrual cup comprising a first step of designing a menstrual cup comprising a receptacle having an exterior surface and an interior surface, the interior surface defining at least in part an interior cavity adapted for collecting fluid, the receptacle further extending from an open top end to a closed bottom end, the open top end having a predetermined diameter, the receptacle further comprising an upper rim portion at the open top end of the receptacle, and a main portion defining a decreasing diameter of the interior cavity while extending downwards from the open top end to the closed bottom end of the receptacle; a second step of obtaining mold tooling configured for the menstrual cup design; a third step of molding the menstrual cup with the mold tooling; and a fourth step of extracting the menstrual cup from the molding. The manufacturing method further comprises the step of manufacturing the menstrual cup receptacle so that it comprises a renewable polymer.
According to the present disclosure, the method for manufacturing the menstrual cup may furthermore comprise the step of selecting a thermoplastic elastomeric material selected from thermoplastic polyurethane elastomers and/or thermoplastic styrene elastomers.
The disclosure also pertains to the use of thermoplastic elastomeric material selected from thermoplastic polyurethane elastomers and/or thermoplastic styrene elastomers for manufacturing a one-period cup.
The present disclosure will be further explained hereinafter by means of examples and with reference to the appended drawings wherein:
A “menstrual cup” is a cup-shaped device to be inserted into the vagina for the reception and containment of menstrual fluid.
The term “renewable material” refers to material composed of biomass from a living source and that can be continually replenished in a rate equal to or greater than the rate of depletion, for example wood, crops, marine products or organic waste.
“Biodegradable material” refers to material that rapidly decomposes by microorganisms and other biological processes. Biodegradation is a chemical process in which materials, with the help of microorganisms, are metabolized to water, carbon dioxide, and biomass.
“Finite sources” relates to resources that are non-renewable such as carbon-based fossil.
As used in this disclosure, “array” refers to a display of packages comprising menstrual cups of different receptacle dimension and/or material hardness but having a similar construction. The packages have the same brand and/or sub-brand and may also have the same trademarks. The packaging elements such as material type, dominant color and/or design) are similar to convey to the customer that the different individual packages are part of a larger line-up. The packages are placed in proximity to each other in a given area in a retail store.
In all figures in the following detailed description, the same reference numerals will be used to indicate the same elements.
The menstrual cup according to the present disclosure may have at least two configurations; a folded configuration for inserting/removing the menstrual cup into the vagina and a deployed configuration during use. The folded configuration is achieved by folding the resilient material of the receptacle 2 along the longitudinal axis. The menstrual cup is inserted into the vagina in a folded configuration with the open top end facing the cervix thus exposing the interior cavity 5 to the cervix for the collection of fluids. Once inserted, the menstrual cup assumes its deployed configuration with the upper rim portion 8 assuming its original circular perimeter to form a seal between the menstrual cup 1 and the vaginal wall.
In
The menstrual cup can be removed from the vagina by pulling the grip 10 extending from the closed bottom end 7. As shown in
The material thickness in the receptacle 2 varies between the different defined portions within the menstrual cup 1. The material thickness in the upper rim portion 8 is greater than the material thickness in the main portion 9 and in the transition portion 11, thus providing the upper rim portion 8 with rigidity for maintaining the menstrual cup in a pre-determined position in the vagina. The material thickness in the transition portion 11 may be greater than in the main portion 9 resulting in an increased sturdiness of the transition portion to support the upper rim portion 8 in retaining the pre-determined shape of the menstrual cup. The material thickness in the receptacle 2 may decrease downwards from the upper rim portion 8 to the closed bottom end 7. The material thickness in the upper rim portion 8 may be about 5 mm. The material thickness in the transition portion may decrease from about 3 mm at the end of the transition portion adjacent to the upper rim portion 8, to about 2 mm at the end of the transition portion adjacent to the main portion. The material thickness in the main portion 9 may be about 2 mm.
The material thickness can be measured using the following method: thickness is measured on the main portion (reference numeral 9 in
According to the present disclosure, an array of menstrual cups may be constructed wherein the receptacle has different dimensions corresponding to varying capacities for receiving liquid. For example, a first article may have a smaller liquid receiving capacity, e.g. 20 ml, a second article may have a larger liquid receiving capacity, e.g. 25 ml. The array may also include a third article having a largest liquid receiving capacity of e.g. 30 ml. The array of menstrual cups may also be constructed such that a first dimension of the receptacle is adapted for users that have not given vaginal birth and a second dimension of the receptacle is adapted for users that have given vaginal birth. The different dimensions of the receptacle may enable the array of menstrual cups to accommodate the physical modifications that are associated with child birth. In general, the dimensions of the receptacle may cover a range of 15 to 50 ml.
Further, an array of menstrual cups may be provided wherein the material constituting the receptacle has at least two Shore A values depending on the user preferences. For example, a first menstrual cup may have a Shore A value within the range of 20 to 30, while a second menstrual cup has a Shore A value within the range of 40 to 50. The array may further comprise a third menstrual cup having a Shore A value between 50 and 70.
An important aspect of the current disclosure is that the production of the menstrual cup has a decreased environmental impact as compared to menstrual cups produced entirely from materials originating from finite sources.
The material constituting the receptacle 2 may be a thermoplastic elastomer to provide the necessary flexibility for the menstrual cup to assume an optimal fit during use and to enable easy folding and deployment. The renewable material in the menstrual cup may be selected from the thermoplastic polyurethane elastomers and/or thermoplastic styrene elastomers. Examples of renewable elastomers are Dryflex® Green by Hexpol TPE and bio TPU™ by Lubrizol. Because renewable thermoplastic elastomers are generally harder and less flexible, it may be advantageous to use a blend of renewable and non-renewable elastomers in the receptacle 2 of the menstrual cup. Thus, the amount of renewable polymer may be present at about 20-100% by weight of the total weight of the thermoplastic elastomer. The renewable thermoplastic elastomer may also be present at about 30-90% by weight of the total weight of the thermoplastic elastomer, 40-80% or 50 to 70% by weight of the total weight of the thermoplastic elastomer. The entire menstrual cup may be constructed from the same material. The thermoplastic elastomer is preferably a medical grade. Because of the health-related risks associated with latex allergies (WU et al. Current prevalence rate of latex allergy: Why it remains a problem? In: Journal of Occupational Health 2016, 58(2): 138-144), the use of latex as a renewable polymer is outside the scope of the current disclosure.
Furthermore, the renewable thermoplastic elastomer in the present disclosure may not be biodegradable as biodegradable polymers have hydrophilic properties which may hinder effective containment of the menstrual fluid in the receptacle.
As described earlier, the material in the menstrual cup wall may be flexible and can therefore easily adapt different configurations for optimal fit into the vagina and for easy insertion and removal. The material may be resilient, so that the menstrual cup restores to its original shape after being compressed. The material hardness in the main portion of the menstrual cup wall may be between a Shore A value of 20 and a shore A value of 70, to provide the required flexibility and resiliency.
The hardness of the material constituting the menstrual cup can be determined through the following method: hardness of the wall material can be quantified in Shore hardness units. The determination is done according to ISO 868 (2003 version), Plastics and ebonite—Determination of indentation hardness by means of a durometer (Shore hardness). The Shore A scale is utilized. A suitable tester is available from Kern, Germany, under the designation Sauter HDA 100-1 (Shore A). The instrument is held against the test object, and an indenter is forced into the object. The hardness is inversely related to the penetration depth of the indenter. Shore hardness is reported on scale ranging from 0 to 100, where higher figures represent harder materials. For the evaluation, the menstrual cup is removed from its package, and is then conditioned for 24 hours in a laboratory environment set to 23° C. and 50% relative humidity. Hardness is measured on the main portion (reference number 9 in
The menstrual cup may be manufactured by injection molding the wall material in the desired unfolded configuration. The mold tooling may consist of several parts that need to be disassembled after the molding step to reveal the menstrual cup end product. Trimming may be required to remove excess material not forming part of the menstrual cup. Alternatively, vacuum forming, die casting, blow molding or extrusion may be used for shaping the wall material in the desired configuration.
Filing Document | Filing Date | Country | Kind |
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PCT/SE2019/050549 | 6/11/2019 | WO | 00 |