CH674915A5 - - Google Patents

Description

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

CH 674 915 A5

description

The present invention relates to a device for regulating plant growth for use in plants, shrubs or trees in containers or in individual plants, shrubs or trees without containers. The expression “plants in containers” in this context means that the plants are grown, for example, in pots, flower boxes, hanging baskets or the like.

Treating container plants or individual plants with plant growth regulators may be desirable, for example, to reduce overproduction of foliage and to produce a more compact type of growth. In the commercial production of plants by plant breeders, growth regulators are usually formulated on a large scale in order to apply to a large number of plants. The generally used application methods include either the root application by a root bath or the structure application by spraying. Other methods are occasionally used, such as immersing tubers in a solution of the growth regulator, for example in the case of tulip bulbs. These application methods require careful calculation of the required amount of plant growth regulator and the volume in which the application is carried out. The calculations depend on the size of the pot, the type of plant and sometimes also the type of growth medium or soil. This calculation can become unnecessary when the device of the present invention is used. Furthermore, the grower does not need to use the usual application methods, but can use comparatively simple methods by placing one or more of the devices according to the invention in the container or in the soil or in the growth medium near the roots of the plants which are not grown in containers are inserted (or positioned depending on the shape of the device). For conventional application methods, the supply of plant regulators in large quantities for farmers or commercial breeders is usually sufficient to treat a very large number of plants. In the home, however, not only is it difficult to dose the correct amount of plant growth regulator, it is also inconvenient for small consumers to apply the correct amount to a limited number of plants, shrubs or trees. Plant growth regulators can be very useful in domestic situations where the plants are grown under low light conditions, which often results in discoloration, or the plants can be over-fertilized, which results in accelerated growth and leads to overgrown, often pale looking plants . These effects can be reduced by using plant growth regulators. The device according to the invention is of help to the domestic user insofar as it contains a known amount of plant growth regulator in a form which is easy to handle in comparison with conventional application techniques.

In particular, it has been observed that the plant-regulating composition not only has a beneficial effect on the growth and shape of the plant, but also that the plants are more resistant to dry conditions, the color of the leaves and flowers is improved, a greater number of flowers is induced and the flowers remain fresh for a longer period than in untreated plants. For commercial growers, it is also desirable that plants or trees or in orchards, in particular those with a limited size, can be individually manipulated. A further use is also possible with ornamental trees, for example with those hems that are lined up on the edge of streets that often require cleaning or pruning.

According to the invention there is provided a plant growth control device which is adapted for use with container and individual non-container growing plants, bushes or trees, which device comprises a molded aggregate of non-fibrous material impregnated with a plant growth control composition.

In use, one or more shaped aggregates are placed in containers of a container plant or near individual plants, bushes, or trees planted in the open ground. When the plants are watered or when it rains or when there is groundwater, at least a portion of the plant regulator composition with which the aggregate is impregnated is dissolved and distributed near the roots. The plant control composition can reach the roots from the surface of the soil, from a location in the immediate vicinity of the root, below the surface of the soil, or, particularly in the case of the container plants, the plant growth regulator can be pulled with the soil water or by fusion from the base of the container towards the roots. The shaped aggregate can serve another purpose, namely simultaneously to fertilize the plants when the non-fibrous material of the aggregate contains all or part of mineral nutrients.

The mineral nutrients can be an additional impregnation agent, but preferably the aggregate can consist entirely or partially of solid mineral nutrients. The mineral nutrients reach the roots in the same way as the plant control composition when the aggregate is dissolved in water. The effect of the mineral nutrients generally causes

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

CH 674 915 A5

mean an improvement or acceleration of the growth of the plants and an improvement in the color of the leaves. However, this often leads to overgrowth and the plants get a pale and useless appearance. The retarding effect of the plant regulating composition in addition to the mineral composition prevents long, prolific growth and improves the color and also the shape of the plant by making it appear more compact. Another advantage of this method is that two effects are combined into a simple and single operation.

Accordingly, the molded aggregate can a) mineral nutrients and binders impregnated with the plant control composition, or b) inert, non-fibrous materials and binders impregnated with the plant growth control composition, or c) a combination of mineral nutrients with inert, non-fibrous Contain materials impregnated with the plant control composition.

The formed aggregates, which consist wholly or partly of mineral nutrients, can contain the main nutritional minerals nitrogen, phosphorus and / or sodium as main components. These nutrients are supplied by well known source materials. Typical source materials are inorganic salts and a typical composition is described in US-A 4,348,218. The total mineral content in the form of swelling materials can be up to 98% by weight of the aggregate. A single nutrient source material can make up up to 98% of the total weight of the aggregate. Typically, each nutrient source material can individually make up from 1 to 60% of the total weight, preferably 5 to 50%, and typically 10 to 40%. The remaining weight of the unit can consist of trace elements such as zinc, manganese or inert, non-fibrous materials. The nutrients that can be derived from the source materials are often given as part of the NPK nutrients. This can vary depending on the needs of the particular plants. NPK typically contains the following ratios: 16: 8: 8, 5: 5: 5 :, 15: 5: 5, 6: 4: 4, 8: 4: 4.

Material which contains the aggregate material / binder is expediently selected from enough porous substances so that the plant regulation impregnation agent can be absorbed.

Inert, non-fibrous materials useful in the practice of the invention include natural or industrial absorbent materials. Examples are pumice stone, silicon oxide, zeolite, alumina, bentonite, kaolinite, diatomite; water soluble salts that form crystalline hydrates; insoluble waxes, for example paraffin wax, beeswax, plant waxes, organic compounds such as stearic acid, fatty alcohols; water soluble waxes, e.g. high molecular weight polyethylene glycols; expanded polystyrene, foamed rubber «Oasis»; Plastics, e.g. PVC, polyethylene; fixed emanators, e.g. Camphor, naphthalene, solid gels made from aqueous polymers ("Air Freshner type"), latex, gelatin. Many of these non-fibrous materials may require binders to convert the aggregates into forms suitable for use with container or individual plants, bushes or trees, and to achieve the necessary strength for insertion into the growth medium. Useful binders include water-soluble binders such as cellulose derivatives, polysaccharides, gums, polyvinyl alcohol, urea formaldehyde or water-insoluble binders such as wood resins, polybutenes, alkyd resins.

Further, surfactants can be added to increase the level of release of the active chemical ingredient into the root zone, or the device can be multi-coated to achieve sustained release over a long period of time. Other techniques can cause delayed or powder-like release. Biodegradable polymers that are decomposed by soil microbes can be used for a delayed release (e.g. polylactic acid).

The molded aggregates of non-fibrous material can have various shapes depending on the requirements of the application, the plant and the consumer. As a result, the aggregate is brought into various forms which are expedient for placement in the vicinity of the plant. Another feature of the molded assembly is that it can be easily adapted for consumer handling by working out the correct dosage and then applying the plant treatment device. If, for example, 1 g of the plant regulating agent per 2.54 cm (1 ") of the diameter of the trunk is required for tree treatment, instead of the release rates and volume for application of a root stain, only the required number of aggregates can be applied to ensure the correct dosage in the Powder and granules are not suitable for this purpose, since this would result in the user having to calculate the correct dosage level for the size of the plant or the container and then weighing the correct amount. The shaped aggregates preferably contain at least one fifth of the required amount of plant growth regulating composition for an individual plant or a container of plants, for example at least half of the amount for an individual plant or a plant container

3rd

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

CH 674 915 A5

and preferably substantially the amount required for a plant or a plant container.

Appropriate forms would therefore be collars or discs for application to the surface of the soil or the growth medium around the base of the plant, tree or bush; Nails, cubes, sticks, capsules, tablets, pills for partial or complete insertion into the soil or the growth medium in the vicinity of the roots; a mat, plate or disc for application near the plants or the container. Mats, plates or discs can be applied in a hole which has been cut out before planting a plant, bush or tree or can be used on the bottom of an empty or partially filled container before planting. If the container has holes for drainage of water or for irrigation, it can be placed on a mat, disc or plate, the plant growth regulating composition and the nutrient composition, if any, being dissolved when the plant is watered, the Solution is transferred near the roots.

The present invention also provides a method for regulating the growth of individual plants, bushes or trees, with or without a container, wherein one or more of the devices described above are applied in the vicinity of the plant or container or on the surface of the growth medium.

The molds from the aggregate can be molded either after impregnation with the plant control composition or before regulation. In the first case, the plant control composition is thoroughly mixed with the mineral nutrients and / or the inert non-fibrous materials prior to forming the aggregate. In the latter case, the shaped aggregates are rinsed with the plant control composition or soaked with the composition. In the context of the present invention, the term “impregnated” refers to both methods of incorporating the active chemical components described here. The plant growth control composition with which the aggregate is impregnated expediently contains the active chemical active ingredient in water or in volatile or non-volatile oils, it being possible to add surface-active agents. The plant growth regulating composition can have a water solubility such that the degree of supply to the plant corresponds to the desired degree of application. It was found that compositions based on the plant regulation compound paclobutrazole (1 - (4-chlorophenyl) -4, 4-dimethyl-2- (1 H-1,2,4-triazol-l -yl) -pentan-3-oI ) are particularly suitable as plant growth regulators. Other plant growth regulating compositions which can be used in the device according to the invention include E-1 - (4-chlorophenyl) -4,4dimethyl-2- (1,2,4-triazol-1-yl) pent-1 -en- 3-ol; (E) -1-cyclo-hexyI-4,4-dimethyl-2- (1H-1,2,4-triazo! -1 -yl) -pent-1-en-3-ol; and 1-phenoxy-3- (1 H-1,2,4-triazol-1-yl) 4-hydroxy-5,5-dimethylhexane.

It is pointed out that the dimensions of the molded units must be adapted to the intended purpose. Accordingly, mats, collars, disks or plates are expediently essentially flat, and nails, cubes, rods, capsules or tablets are usually extruded to a greater or lesser extent. Round objects, e.g. large pills can also be used provided they are large enough for easy handling. Flat aggregates can accordingly be rolled up between 0.1 mm and 300 mm, in particular 0.1 to 100 mm and typically 0.1 to 50 mm in thickness. The length, width or diameter can be determined by the size of the plant to be treated. The extruded aggregates can have a length of 5 mm to 400 mm, preferably 10 to 200 mm and typically 10 mm to 60 mm. The diameter or the width can be 3 mm to 150 mm, preferably 3 mm to 100 mm and typically 3 mm to 80 mm. Accordingly, a pill can have a diameter of 0.5 mm to 100 mm, preferably 0.5 mm to 50 mm and typically 0.5 mm to 20 mm. Pills with dimensions smaller than those described here are less desirable for the reasons given above in connection with the use of granules.

The amount of the active chemical substance in the shaped aggregates depends on the size of the aggregates, which in turn depends on the size of the plant, the tree or the bush and whether they are planted in a container. The amount of active growth regulator component per molded aggregate can be 0.1 mg to 20 g, preferably 0.5 mg to 15 g, typically 1 mg to 10 g of active ingredient. In some cases, more than one unit can be used to achieve the correct dosage level. In some circumstances, it may be necessary to remove the aggregate from the growth medium after a certain period of time, for example when the growth-regulating effect has been achieved or when the plant is moved or sold; Accordingly, aggregates of essentially inert materials with an insoluble binder are desirable for this purpose.

example 1

The effect of thorns impregnated with paclobutrazole was determined on four plants. The thorns, which consisted essentially of mineral material held together with urea-formaldehyde, were impregnated with a solution of paclobutrazole in methanol and the Lö4

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

CH 674 915 A5

Solvent was allowed to volatilize to give 0.05, 0.5 and 5 mg per mandrel. The thorns were identical for nutrient thorns, which are commercially available under the trade name KERISPIKE (Imperial Chemical Industries PLC) and have a diameter of approximately 5 mm and a length of 40 mm and an NPK ratio of 6: 4: 4.

These thorns were inserted into pots containing plants grown in peat. During the treatment, the main shoot of each plant was about 20 cm long.

The growth was measured and the delay was determined at the time when the growth of the untreated ivy plants was 13 cm and the shoots of the Tradescantia fluminesis (Wandering Jew) and the orange plant had grown to 13.4 cm and 13.8 cm, respectively .

The results are shown in Tables I - III below. A darker green, thicker leaves were observed in all plants, along with a delay in the growth of the shoot.

Table I

Delay in ivy concentration of paclobutrazole in the thorn (mg per thorn)

Rhoicissus increase in height 75 DAT

(% of control)

Sheet size,

visual delay (% of control) 75 DAT

0.05

36% *

70%

0.5

35% *

60%

5

28% *

50%

DAT = days after treatment

* = the results given were statistically significant (only measured variables)

Table II

Delay in Tradescantia fluminesis f Wanden na Jew)

Concentration of paclobutrazole in the thorn (mg per thorn)

Shoot growth 29 DAT

(% of control)

Sheet size,

visual delay (% of control) 75 DAT

0.05

96%

50%

0.5

69% *

30%

5

64% *

20%

DAT = days after treatment

* = the results given were statistically significant (only measured variables)

Table III

Delay on the orange plant - Solanum concentration of paclobutrazole in the thorn (mg per thorn)

Shoot growth, 75 DAT (% of control)

0.05

77% *

0.5

57% *

5

56% *

DAT = days after treatment

* = the results given were statistically significant (only measured variables)

5

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

CH 674 915 A5

Example 2

The effect of pplobutrazole-impregnated food thorns and mats on height and plant quality was tested using potted plants. The dimensions of the dome were 5 x 44 mm and those of the mat were 5 x 60 mm. The mandrel was obtained and impregnated as in Example 1. The mat was made by grinding thorns and shaping the nutrient material into a mat. The mat composition was 96% ground "thorn" powder and 0.4% hydroxycellulose (binder). The domes and mats were impregnated with a solution of paclobutrazole in methanol and the solvent was evaporated to give 0, 2 and 1 mg per mandrel or mat.

The Hypoestes plants were grown in peat in 10 cm (4 ") pots and treated with one spike or mat per pot. The plants were propagated from seed and treated when they reached 4 cm in height. The domes were placed in the pots were inserted and watered from the top of the plant, the mats were placed under the pots and the plants were watered from below, each treatment was carried out in triplicate.

Growth was measured and visual assessment of leaf color and plant compactness was taken. The results are shown in Table IV, the percentage of the delay relative to the untreated control plants being shown and the color and plant form being assessed on a scale from 0 to 3, 3 being the best color or plant form.

Table IV

Treatment mg ai / pl.

% Warped 0-25 DAT

% Warped 0-33 DAT

colour

Plant shape

mandrel

0

-7

-1

0

0

0.2

48

62

2.3

1.7

1.0

42

68

2.7

2.3

mat

0

28

32

1.0

0

0.2

37

45

2.0

0.7

1.0

56

57

2.0

1.3

(-) means increased growth compared to the control plants

The results for the thorn show that without growth retardation there was a slight improvement in growth compared to the total untreated control plants. This illustrates that the problem can arise when the addition of nutrients leads to accelerated growth, which often results in proliferation. The effect of the growth retardant in addition to the nutrients is clearly the control of the growth and the improvement of the quality of the plant, as can be seen from the effect on the color and plant shape. The non-impregnated mat showed delay effects, which primarily resulted from watering the plant from the underside and from absorption of the water by the mat. The paclobutrazole impregnated mat caused a greater delay than the non-impregnated mat and also improved the plant quality.

Example 3

This example illustrates the use of two paclobutrazole-impregnated thorns, one of which (mandrel A) was based on the mineral nutrient according to example 1. The other (Dorn B) was based on an inert non-fibrous material and did not contain any mineral nutrients. The inert mandrel was formed from the following components:

Hydroxyethyl cellulose

0.4% by weight

Sodium lignosulfonate

5.0% by weight

binder

Synperonic NX

0.3% by weight

Extruding acid

Porcelain clay GTY

ad. 100% by weight

filler

Hypoestes plants were propagated and treated in exactly the same way as in Example 2. Each treatment was done in triplicate.

6

5

10th

15

SO

25th

30th

35

40

45

50

55

60

65

CH 674 915 A5

The growth was measured and the plant color and compactness of the plant were assessed visually. The results are shown in Table V as a percentage delay, compared to untreated control plants, and the color and plant shape were rated on a 0-3 scale, with 3 being the best color or shape.

Table V

Treatment mg ai / pl.

% Warped 0-25 DAT

% Warped 0-33 DAT

colour

Plant shape

Dorn A

0

2nd

8th

0

0

0.2

54

65

2.0

2.0

1.0

75

79

3.0

2.7

Thorn B

0.2

32

43

1.3

0

1.0

62

76

2.7

2.0

The results of this test show that the part of the delay was approximately 1 mg per plant and was slightly larger with the food spike (A) at 0.2 mg per plant. However, there were quality differences in addition to those of the color and plant shape. The nutrient-bearing mandrels gave the better color and shape than the nutrient-free mandrels, although both mandrels gave considerably better plant quality compared to the nutrient mandrel which did not contain a plant growth regulator.

Example 4

This example illustrates the plant growth regulation of the Hypoestes pot plant using mineral nutrient thorns (as described in Example 1), which are treated with (E) -1-cyclohexyl-4-4-dimethyl-2- (1H-1,2,4-triazole- 1-yl) -pent-1-en-3-oI were impregnated. The Hypoestes plants were propagated and treated as described in Example 2. The treatment was carried out in triplicate.

The growth was measured and the leaf color and compactness of the plant was assessed visually. The results are shown in Table VI, the percentage showing lag compared to the untreated control plant, and the color and plant shape were rated on a 0-3 scale, with 3 being the best color or plant shape.

Table VI

Treatment mg ai / pl.

% Warped 0-25 DAT

% Warped 0-33 DAT

colour

Plant shape

mandrel

0

-7

-1

0

0

0.2

46

61

2.3

1.7

1.0

65

75

3.0

2.7

The results of this test show that the compound (E) -1-cyclohexyl-4,4-dimethyl-2- (1H-1,2,4-triazol-1-yl) -pent-1-en-3-ol is the same and effective in the present invention as paclobutrazole.

Example 5

This example illustrates the use of nutrient thorns impregnated with paclobutrazole on set bushes planted in the open ground (i.e. not in containers). The thorns each weighed 6 g and had a size of 15 x 45 mm and contained 16: 8: 8 NPK. Plants of Cornus alba (hornbush) and Cotoneaster decorata were treated in spring by putting five spines straight into the ground 10 cm from the main stem, i.e. around the tribe. Each mandrel contained either 5 mg or 25 mg paclobutrazole per mandrel. Each treatment was carried out five times.

For comparison, a paclobutrazole root bath was also applied to some shrubs. The root bath was applied with an amount of 25 mg of active ingredient per plant with a bath volume of 400 ml per plant. The bath was poured into a shallow trench, which was dug around the stem of the plant and 10 cm from the main stem.

6 shoot lengths per plant were measured for 6 months and compared with the untreated controls.

7

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

CH 674 915 A5

The results are shown in Table VII as a delay percentage based on the untreated controls.

Table VII

Treatment mg / ai

% Delay Cotoneaster

Cornus alba

Cathedral

25th

88

14

125

88

50

Root bath

25th

80

-15

(-) indicates that the plants grew larger than the untreated controls.

These results show that the cotoneaster bushes are very sensitive to the plant growth regulator and that the amounts used seemed to cause a maximum, achievable delay when they were applied by the dome application. Nevertheless, the 25 mg per plant treatment was more effective than the equivalent root bath. The results of the same treatments on Cornus alba showed that the thorn treatment was superior to an equivalent root bath.

Example 6

This example illustrates the use of nutrient thorns impregnated with paclobutrazole on planted trees that have been planted in the open ground (i.e. without a container). The thorns each weighed 50 g and had a dimension of 30 x 100 mm and contained 16: 8: 8 NPK.

Two 5 year old cherry trees were treated by putting 5 x 50 g thorns in holes that were just arranged around the tree trunk. Each mandrel was impregnated with 1 g paclobutrazole with 5 g paclobutrazole applied per tree. For comparison purposes, two trees were treated with a collar bath in the usual way. The amounts applied in the thorn treatment and the collar bath treatment were equivalent to 1 g per 2.54 cm (1 ") diameter of the tree. The trees were treated in late spring and were treated for treatment effects approximately 4 months later at the end of the growing season The retarding effect was assessed by measuring the growth of the final shoot of the treated trees and comparing the result with the final shoot growth of the control trees The results are shown in Table VIII as a percentage delay relative to the control.

Table VIII

Treatment g / plant

% Delay

Cathedral 5

57 *

Collar bath 5

*

CO CO

* not noticeably different from each other.

The results of this test and the previous test (Example 5) show that the mandrel method of treatment is usually as effective, if not more effective, than the root or collar bath method of applying plant growth control compositions. Furthermore, the bath method first requires a calculation of the amount and volume of a particular composition required to achieve an effect and then the user must determine the weight or volume of the concentrated plant growth regulator and formulate a composition according to the instructions and then the composition in a pot, a dug gutter or poured into the ground around the tree or bush. It can be seen that this is a time consuming process. The advantage of the mandrel (over any other form of aggregate described here) is that it contains a known amount of plant growth regulator and the user can use as many as necessary to achieve the desired effect. Often, the user only has to put the mandrel into the ground, for example, or dig a small hole in the case of a larger dome to accommodate the mandrel near the roots.

Claims (12)

Claims 1. device for regulating plant growth for use in plants, shrubs or trees in containers or in individual plants, shrubs or trees without containers, 8th 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 CH 674 915 A5 characterized in that it contains molded aggregates of non-fibrous material impregnated with a composition for regulating plant growth. 2. Device for regulating plant growth according to claim 1, characterized in that the shaped aggregate contains a composition of plant minerals in addition to the composition for regulating plant growth. 3. Device for regulating plant growth according to claim 1 or 2, characterized in that the non-fibrous material contains all or part of a solid nutrient composition. 4. Device for the regulation of plant growth according to one of claims 1-3, characterized in that the non-fibrous material is bound to form the shaped aggregate by means of a binder. 5. A device for regulating plant growth according to claim 3, characterized in that the nutrient composition contains mineral nutrient salts, the mineral containing at least one component nitrogen, phosphorus or sodium, the total mineral nutrient content of the aggregate not exceeding 98% by weight of the total weight of the unit is. 6. Device for regulating plant growth according to claim 5, characterized in that each of the nutrient salts contains individually 1-60 wt .-% of the total weight of the aggregate. 7. Device for regulating plant growth according to one of claims 1-6, characterized in that the shaped unit has the shape of a dome, a block, a stick, a tablet or a pill, which is partially or completely for the introduction into the Growth medium are adapted or are in the form of a mat, plate, disc or collar which are adapted to be positioned either near the plant or container or on the surface of the growth medium. 8. Device for regulating plant growth according to one of claims 1-7, characterized in that the shaped unit has a length of 5 to 400 mm and a diameter or a width of 3 to 150 mm. 9. Device for regulating plant growth according to one of claims 1-7, characterized in that the shaped unit has a thickness of 0.1 to 300 mm. 10. Plant growth regulating device according to one of claims 1 to 9, characterized in that the shaped aggregate contains 0.1 mg to 20 g of an active plant growth regulator component. 11. Device for regulating plant growth according to one of claims 1-9, characterized in that it contains a plant regulating agent composition which contains at least one of the following compounds: (1- (4-chlorophenyl) -4,4-dimethyl-2- (1H-1,2,4-triazol1-yl) pentan-3-ol); E-1 - (4-chlorophenyl) -4,4-dimethyl-2- (1H-1,2,4-triazoI1-yl) -pent-1-en-3-ol; (E) -1-cyclohexyl-4,4-dimethyl-2- (1H-1,2,4-triazol-1-yl) pent-1-en-3-ol; and 1-phenoxy-3- (1 H-1,2,4-triazol-1-yl) 4-hydroxy-5,5-dimethyl-hexane. 12. Commercial process for regulating the growth of individual plants, shrubs or trees with or without a container, characterized in that one or more devices for regulating plant growth according to one of claims 1-11 near the plant or the container or the surface of the growth medium are brought into position. 9