NO135675B - - Google Patents

Description

Fungal sprayer for treating weed plants with chemicals.

Chemical agents against weeds are increasingly being used. The most used chemicals today are the so-called hormone preparations (2,4-D and 2M-4Km. etc.) which have a selective effect on many of our worst weed species in cornfields and grassland when the preparations are mixed with water and sprayed over covered in growing crops. These chemicals are systemic, i.e. they can be taken up through leaves and stems and transported further to roots and other plant parts through the plant's conduction system. They therefore also kill the underground organs of perennial weeds, such as dandelion, giant, coltsfoot, hay mole, thistle and field gorse etc. Because the chemicals are spread inside the plant, the effect is little dependent on the amount of water they are sprayed into. It is therefore not necessary to wet all the foliage. A single drop per plant may be enough. For dandelions, an e.g. using radioactive 2,4-D can only show that the most favorable location will then be on the midrib at the bottom of the leaf plate.

As mentioned, the hormone preparations have a selective effect in cornfields and grassland, i.e. they kill weeds without causing permanent damage to cereal and grass species.

But the aforementioned weed species also grow

often between cultivated plants that cannot tolerate coming into contact with hormone preparations. This is the case with most perennials and other ornamental plants. In such places, there is therefore a great need for a tool for easy-to-use treatment of each individual weed plant with herbicides (plant-killing chemicals) in such a way that there is no risk of damage to the crops. Individual treatment of scattered weed plants in lawns and pastures may also be relevant

because it would then be an unnecessary expense to spray the entire area.

Different types of stick sprayers and stick sprayers are previously known, which use a piston pump to spray out a diluted solution in a more or less fine shower over the leaves or as a jet through a needle-shaped tip that is inserted into or next to the root to each weed plant. There are also wand sprayers with a relatively wide funnel-shaped screen around the spray shower.

The disadvantage of all known tools of this type is that you have to use a relatively strong dilution of the chemicals, so the syringe gets a relatively small capacity for each refill, and that you cannot place the syringe fluid particularly precisely, so that the risk of harmful effects is always present. in larger or smaller quantities.

The present inventions aim to solve these problems in a simple and inexpensive way. This is achieved according to the invention by building on the capillary principle. The capillary conductivity in a sponge body depends on the size of the pores. If, in a per se known type of a walking stick-like syringe, made of plastic tubes or metal tubes, one places a synthetic sponge plug, here called a sponge valve, between two sieve plates under the spray liquid in such a way that the distance between the sieve plates can be regulated , e.g. by screwing the liquid tube into a sleeve that surrounds the sponge plug, you will get a larger or smaller liquid passage depending on the degree of compression. When the sponge is pressed completely together, it will be as tight as a cork, so that the rest of the spray liquid does not need to be emptied when the syringe is put away for later use. The strainer plates must be sufficiently rigid to withstand the pressure to which they are exposed, and provided with many and sufficiently large holes to ensure a free passage of liquid.

The valve sponge should otherwise be so fine-pored that it only has capillary conductivity, even without compression, to prevent the liquid from flowing through due to the hydrostatic pressure. The sponge must have a slightly larger diameter than the pipe so that it exerts an elastic pressure against the pipe wall to prevent non-capillary channels from being created here. In addition, it must be made of a material that can withstand acids and alkalis and mineral oils. Polystyrene was supposed to be an eg-net material.

Below and in direct contact with the lower sieve plate, which is on a locking ring or studs in the pipe wall, another sponge is placed, here called the "sponge nozzle" which can be a uniform thick round pin with a slightly larger diameter than the diameter of the pipe (sleeve), so that it must be pressed together somewhat when inserted into the sleeve so that it does not fall out during use. Also, it must protrude a little below the end of the pipe and should be hemispherical at the end. When this sponge nozzle is placed in the middle of a rosette-shaped weed plant, e.g. dandelion, the spherical shape will provide the most favorable contact surface. The contact surface will also be smaller on small weed plants than on larger ones, so that the amount of preparation will to a certain extent be automatically adapted to the plant size.

The amount of liquid can otherwise be regulated by the degree of compression of the sponge nozzle. The stronger the compression with each impact against the weed and the underlying soil, the greater the fraction of the sponge emits of its capillary fluid. When the stick is then quickly lifted up again, the sponge will expand and exert a suction effect on the sponge valve and replace the lost liquid from the reservoir above.

A further feature of the invention is that the compression of the sponge nozzle, and thus the stroke volume of the "sponge pump", can be regulated by means of a screw sleeve which encloses a larger or smaller part of the free end of the sponge nozzle. This sleeve also serves as protection against surrounding cultivated plants coming into contact with the spray liquid when the tool is moved approximately vertically between the plants.

In order to increase the sponge nozzle's contact surface with the weeds, it can be given a spherical extension at the lower end, so that the entire sponge nozzle takes on a light bulb-like shape. The two sleeve pipes must then have corresponding extensions. Reference is also made to the attached drawings, which will be explained in more detail.

Fig. 1 shows in perspective a sponge syringe according to the invention. Fig. 2 schematically shows a longitudinal section of the lower working part of the syringe according to the invention. Fig. 3 likewise schematically shows a longitudinal section of another design of the syringe's working parts according to the invention. Fig. 1 shows a sponge syringe with a rod-shaped tube a, which can be screwed into the sleeve 3, which encloses the upper part of the sponge nozzle d, which is seen as a hemisphere at the end of the tool.

At the upper end of the tube a, a handle e is mounted, which can be fixed, or preferably threaded like a screw cap, and provided with an air valve f, to avoid a vacuum over the liquid as it is pumped out. Fig. 2 shows that the pipe a serves as a reservoir for the spray liquid v. When the pipe a is screwed into the sleeve b at the screw threads g, the end of the pipe will press the valve sponge s together against the lower sieve plate w which is stopped by the barrier r. Between the pipe a, and the strainer plate q, an annular rubber gasket p is placed to prevent the liquid from seeping out through the screw passage g. The liquid which is guided capillaryly through the spigot t of the sponge nozzle and down into its lower free end d, which is part of a spherical surface that will transfer some of the liquid to the weed plants by direct contact with them. By screwing the sleeve c more or less far down using the screw thread u, the compression of the sponge, and thus the amount of liquid released for each shock, can be easily regulated as desired and needed. Fig. 3 shows the same principle with the same letter designations for the different parts of the syringe. The only difference from the embodiment in fig. 2 is that fig. 3 shows how the sponge nozzle's contact surface with the weed plants can be significantly increased without the pipe a having an unsuitably large dimension. This is achieved according to the invention by giving the sponge t a spherical extension d. At the same time as the sleeves b and c are given a shape that fits this nozzle shape, as shown in the drawing.

The sponge sprayer according to the invention should be able to be used for spray liquids of any concentration, as the liquid passage in the sponge valve can be regulated within the entire area in question. There should be nothing in the way of using liquid herbicides unmixed, or only slightly diluted with water or oil. Various commercial preparations of the hormone type contain from 10 to 50 per cent active substance.

The tube a can therefore be provided with a scale

from 10 to 50 percent, which indicates how long the pipe is

a must be screwed into the socket b depending on the concentration of the preparation used.

The sleeve b can also be fitted with a scale

which indicates which position the sleeve c should be in

have when treating various weed species.

Fungal sprays according to the invention should

also be suitable for stump processing

and so-called poison chopping, where the chemical is placed in an ax cut around the stem of it

three to be killed.

The syringe can of course be given to many others

embodiments and sizes without deviating from the idea of the invention. Thus, it can

miniature syringes are also made according to the same

principle, but intended for treatment of

potted plants etc. 1. with e.g. insecticides

and/or fungicides.

Claims (5)

1. Sponge sprayer for individual treatment of weed plants with chemicals, characterized in that the needle or nozzle in a known type of stick sprayer is replaced with an elastic sponge body (here called a sponge nozzle) which emits a certain amount of spray liquid to the plant to be treated is acted upon when the sponge nozzle is bumped against this or possibly the underlying soil surface. 2. Sponge sprayer according to claim 1, characterized in that the liquid supply to the sponge nozzle is regulated by means of a capillary valve between the liquid and the nozzle, e.g. by placing an elastic sponge body between two sieve plates whose distance can be regulated by screwing the liquid tube into a sleeve which encloses the sponge valve and the upper end of the sponge nozzle. 3. Sponge sprayer according to claims 1 and 2, characterized in that the length of the free end of the sponge nozzle is regulated by means of a screw sleeve, so that the amount of liquid emitted at each impact with the sprayer is constant, but different for different free nozzle lengths. 4. Sponge sprayer according to claims 1-3, characterized in that the contact surface of the sponge nozzle with the plant is part of a spherical surface. 5. Fungal spray according to any one of claims 1-4, characterized in that its size and shape are adapted for treating potted plants etc. 1. with insecticides or fungicides.