NL1039554C2 - PLANT. - Google Patents

Description

Plant

The present invention relates to a pot plant or other living plant whose flowers are artificially colored, such that one or more flowers of this plant comprise at least two colors in addition to its natural color or colors. The invention also comprises a method with which obtaining pot plants with multicolored flowers can be achieved.

The coloring of cut flowers by placing the end of a stem of a branch provided with one or more flowers in a solution comprising a dye is already known. Such a method is described inter alia in Dutch patent NL 1030378.

The method according to that patent also comprises of cleaving the end of the stem 15 in the longitudinal direction before or during the placing of the end of the stem in the solution, so that particles form. The different substituents are then each placed in a container that is filled with a solution of a different color. This method ensures that a single cut flower can get multiple colors and that flowers from one branch can get different colors. This method is of course not applicable to pot plants or other living plants.

Coloring one or more flowers of a pot plant also belongs to the prior art. From NL 2003621 a method for coloring a flower to a pot plant is known, which comprises arranging a bore in the stem of the flower of the pot plant, after which a pipette is placed in the bore and the pipette is subsequently filled with an amount color liquid which can be absorbed by the plant through the bore. This is a passive coloring method, which means that the transport of the dye is completely dependent on the natural transport via that part of the plant's xylem that communicates with the xylem in which the bore is fitted. It is therefore not possible with this method according to the prior art to adequately control the route of the dye.

It is an object of the present invention to provide pot plants or other living plants with, with the aid of the addition of dyes colored, hereinafter also also artificially colored, multicolored flowers. It is also an object of the invention to be able to achieve this preferably in a relatively simple manner, in order to limit the costs of the coloring process as much as possible. In the remainder of this description, the term "plant" will be used for all pot plants and other living plants to which the invention relates, including garden plants. Some examples of plants that are part of the invention are rose bushes, (potted) orchid, phalaenopsis, anthurium, hydrangea, (potted) lily, (potted) gerbera.

The present invention relates to a plant whose flowers are artificially colored and in such a way that one or more flowers of the plant comprise at least two colors in addition to the natural color or colors. By artificial coloring or coloring of flowers is meant here by administering one or more colorants to the plant in any way, which colorants cause at least one flower of the plant, in addition to the natural color, by internal transport via the vascular bundles , comprises at least two colors. In the remainder of this description and in the claims, a reference to "at least two colors" of a flower refers to at least two colors which are clearly perceptible to the human eye and which are mutually different. A color perceptible to the eye as one color which is produced by mixing two or more mutually different colors of added dyes is considered as one color in the present context. A flower which, in addition to the natural color or colors, comprises at least two artificially applied colors, may also be referred to hereinafter as a multi-colored flower for the sake of simplicity. The gradations of a color visible in a flower, which differ from one another in terms of intensity and saturation, are considered as one color in the present context. The invention also comprises a method with which obtaining plants with multicolored flowers can be effected

The invention will be elucidated on the basis of a figure with a description of the color shade of the flower shown diagrammatically in the figure and on the basis of the description of exemplary embodiments of the methods for obtaining artificially colored multi-colored flowers on a plant.

3

In the drawings: Fig. 1 shows a schematic representation of an artificially colored multicolor flower of a pot plant according to the invention.

5

The methods for obtaining artificially colored multi-colored flowers from plants include, for example, injecting a solution with dye at various locations in the plant with the aid of an injection needle. In an exemplary embodiment of the method according to the invention, for example, a first clamp in the immediate vicinity of the root of the plant is injected above the root in the plant, a second color in a leaf and a third color in the end of the stem . Instead of injecting dye into a leaf, it is also possible to cause damage, for example a cut, to the leaf and to place this injury of the leaf in a solution with dye. The same applies to the end of a stem. It can also be cut or incised, for example, and then placed in a colorant solution.

The dyes used for coloring the flowers of plants preferably include, but are not limited to, dyes which are also used for coloring foodstuffs or for coloring cut flowers.

The methods according to the prior art for artificially coloring flowers of a plant all use the natural water transport direction via the xylem. This concerns a direction of transport from the root to the leaves and the growing points, which for most plants includes the direction from bottom to top. With hanging plants, in which the root, normally, forms at least substantially the highest part of the plant, the natural transport actually takes place from top to bottom. In addition, for example, the method described in Dutch patent specification NL 2003621 makes use of applying the color liquid without overpressure to a pot plant. The introduction of dye liquid into the plant by the method according to the present invention by injection involves overpressure administration. The introduction of color liquid under overpressure into a plant results in a faster coloring and moreover in a more controllable coloring of flowers than the known method at atmospheric pressure.

4

The method according to the invention also comprises, inter alia, a small extent, for example about 1 centimeter, shortening the stem at the end of the flowers and subsequently injecting the dye therein. The dye then moves against the natural water transport direction of the xylem. This is achieved by drying out the plant or a part thereof to some extent, as a result of which an underpressure can arise in the xylem and the colorant introduced into the stem above a flower, for example, down against the natural transport direction, towards the flower, is being transported. By providing variation in the time of injection and in the degree of dehydration and thus in the degree of underpressure, the injected liquid can preferably be led to a specific location. This method is completely new and not obvious to the person skilled in the art. Thanks to the creation of underpressure, the process steps in accordance with this method can proceed relatively quickly and be well controlled.

15

Although not always a requirement, the use of the method according to the invention usually starts with the application of the darkest color or colors and the injection or other type of administration of a lighter color follows at a later time. The method thus comprises preferably maintaining the order of administration of dyes from darker to lighter colors.

A plant which, for example, was first injected from below with a light blue dye is injected with yellow after a few weeks. This can result in a flower of which parts turn yellow, parts which were light blue after the previous injection with light blue dye and parts remain light blue. In this way a tri-color flower has already been created in one and the same plant by injecting two different colors at two different times. You can choose whether the two injections take place at the same place (for example in a branch) or at different places.

The method according to the invention comprises many variables to choose from, including the interval between the times of administration and the location of administration in general and the choice between a location that upstream or downstream with respect to the natural water transport direction in the xylem is located in relation to the flower or flowers to be colored.

FIG. 1 is a schematic representation of a flower of a pot plant, the phalaenopsis, wherein the vascular bundles 1 are drawn in one petal. The other petals, of course, also include vascular bundles, but for the sake of convenience these are not shown in the figure.

The color scheme of this exemplary embodiment of a flower according to the invention, which flower is naturally white, will now be summarized briefly. The vascular bundles in all the petals of this flower have essentially a cerise to bright red color, hereinafter also referred to as red for the sake of simplicity. The petal shown at the top right of the flower comprises, in addition to the substantially red vascular bundles (not shown), a number of differently colored surfaces. The two planes with the reference numeral 2 in this exemplary embodiment have a substantially light blue color. The two faces with the reference numeral 3 have a substantially yellow color in this exemplary embodiment. And the surface 4 comprises a substantially pink color. The surface 5 is part of a lip of the flower and comprises a substantially cerise color. The surface 5a of the lip has a dark blue color and the edge of the lip is substantially yellow.

In addition to the substantially red vascular bundles, the two petals 6 have a substantially light blue color with a yellow color or a yellow glow on and in the immediate vicinity of the edges of the petals. The petal 7 comprises substantially red vascular bundles, a surface located in the middle part of the petal with a substantially light blue color, which surface is flanked by partly white and partly yellow surfaces.

A practical example of an embodiment of a method for artificially producing a multi-colored flower on a pot plant, more particularly a flower such as the flower of a phalaenopsis described above, will now be described. This practical example included a phalaenopsis which at the start of the staining treatment included ten flowers, four of which were open. The process included the following steps or phases: 6 a. Injecting a light blue dye into the vascular bundles in the vicinity of the root above the root. This resulted in the light blue coloring of the lips of most flowers; b. The vascular bundles of the four opened flowers were light blue, while the flowers still closed at the time of the injection of the light blue dye opened in the weeks following the injection with light blue spots in the center of the petals.

c. The injection of a cerise dye above the root in the immediate vicinity of the root, approximately three weeks after the injection mentioned in point a. At that time, nine out of ten flowers of the plant were open.

d. The vascular bundles of the four flowers that were first open showed a mixed color of cerise and light blue, hereinafter also referred to as milka color.

e. The lips of the flowers colored from dark blue in the case of the lips 15 of the flowers closest to the injection site to milka colored in the case of the flowers further from the injection site. The ratio between the amount of light blue dye and cerise dye determines which color is ultimately produced on site. Not every flower and lip receives the same amount of dye When injecting two dyes in time, not every flower receives these dyes in the injected ratio. This leads to mutual color differences between the flowers.

f. The next step involved allowing the flowers to dry out to a limited extent, after which a piece, in this case a piece of, for example, approximately 1 cm in length, was cut off from the stem. The wounded end of the stem was then immersed in a yellow dye. As a result of the reduced pressure in the xylem system due to the limited dehydration, the yellow dye was sucked up via the end of the stem and transported to the stem and to the flowers, thus against the natural flow direction of water in xylem.

g. The yellow dye sucked up via the end of the stem resulted in the vascular bundles of the flowers closest to the end of the 7 stem becoming yellow and the vascular bundles of the flowers located farther from the end of the stem a mixture of the blue and cerise dye already present in different concentrations with the yellow dye. This resulted in the bright red vascular bundles mentioned in the description of FIG. 1 5, in which the yellow color, as a light color, was not observed per se. The flower described in Fig. 1 was therefore a flower located further from the end of the stem.

h. The yellow dye introduced via the end of the stem is not only absorbed in the vascular bundles of the flowers, but also spreads in the petal, resulting in the described yellow glow.

i. As indicated in the above description of the flower shown diagrammatically in Fig. 1, the lips comprise the colors blue, cerise and yellow from the inside to the outside, respectively. In addition, the blue that was originally light blue by mixing with the second-injected cerise dye has turned dark blue and the cerise dye is drawn further into the lips than the blue because the lips were developed further than at the time of the injection of the cerise dye time of the blue dye injection. Eventually the yellow colorant is drawn into the fully developed lips and this has resulted in the yellow edge of the lips without a very clear influence on the blue and cerise areas. The yellow has only a somewhat soothing influence on the cerise of the lips.

The method described above for artificially coloring one or more flowers of a pot plant in such a way that these flowers or flowers obtain a shade of color which corresponds in outline to the color shade of the flower shown diagrammatically in Fig. 1 is only one of many possible methods to achieve comparable or different multi-colored, artificially colored flowers of a plant.

Due to the variables such as the order of injection, the time intervals between injections, color types (for example pastel or hard), colorant concentrations, the application sites in the plant, the speed of administration (under overpressure, underpressure or atmospheric pressure), the duration of varying the injection, etc. and / or making other combinations of these variables, an almost unlimited number of multi-colored flower variants can be created.

The present invention comprises any plant with at least one artificially colored multi-colored flower of which at least one multi-colored flower comprises two or more colors in addition to the natural color or colors.

The present invention also relates to a plant which comprises a first flower which comprises, in addition to the natural color, only one, artificially produced color and at least a second flower which comprises, in addition to the natural color, only one, artificially produced color wherein the artificially produced color of the first flower and the second flower, respectively, are two colors that are clearly perceptible to the human eye and that are different from each other.

The exemplary embodiments of artificially colored multi-colored flowers of plants and of methods for effecting this artificial coloring discussed in this description and shown in the figure are only some of the many embodiments possible within the scope of the invention and therefore serve as non-limitative to be considered.

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Claims (9)

A plant, characterized in that, in addition to their natural color, flowers of the plant comprise at least two colors produced by internal administration of colorant. 2. Plant as claimed in claim 1, characterized in that the plant comprises at least one flower colored by artificial means, said at least one flower comprising at least two colors produced by the artificial coloring. 3. Plant as claimed in claim 1, characterized in that the plant comprises at least a first flower which, in addition to the natural color, comprises only one artificially produced color and at least a second flower which, in addition to the natural color, comprises only one artificial color. color produced in which the artificially created color of the first flower and the second flower, respectively, are two colors that are clearly perceptible to the human eye and that are different colors. Plant according to one or more of claims 1-3, characterized in that the plant comprises a rose bush, phalaenopsis, orchid, anthurium, hydrangea, lily or gerbera. A method for obtaining a plant according to one or more of the claims 1-4, characterized in that the method of administering to the plant at at least two places or at least two different times in the plant dye in a form in which the dye can be transported via the xylem. Method according to claim 5, characterized in that applying the dye to the plant comprises introducing the dye into the plant under overpressure. A method according to claim 5 or 6, characterized in that the colorant is applied to the plant at a location located downstream of the flower or flowers to be colored with respect to the normal water transport direction downstream of the flower or flowers to be colored. 8. A method according to claim 7, characterized in that the administration of the colorant is preceded by the induction of underpressure in the xylem of at least a part of the plant due to dehydration. 1 0 3 9 5 5 4 A method according to claim 7 or 8, characterized in that the administration comprises wounding a leaf, branch or stem of the plant and then placing the injured part of the plant in a solution with dye. 5 15 20 25 30 1039554