DE102020103062B3 - Method for claw treatment and device therefor - Google Patents

Abstract

The invention relates to a method for claw treatment in animals, in particular cattle, in which the claws are sprayed with a treatment liquid, characterized in that water is used as treatment liquid, into which ozone is injected under pressure and the ozone-containing water then when a claw is detected is sprayed specifically on the claw area of the animal.
The invention also relates to a device for treating the claws of animals, in particular cattle, in which the claws are sprayed with a treatment liquid, with a supply unit (1) for providing the treatment liquid and an application unit (2), which has at least one spray nozzle (22) and detection means (23) for detecting the animal to be treated, characterized in that the supply unit (1) has an ozone generator (11) and a water supply in order to provide ozone-containing water.

Description

The invention relates to a method for the treatment of claws in animals, in particular cattle, in which the claws or the foot, in particular the skin of the toes, are sprayed with a treatment liquid. The invention also relates to a device for this, in which the claws are sprayed with a treatment liquid, with a supply unit for providing the treatment liquid and an application unit which has at least one spray nozzle and detection means for detecting the animal to be treated.

Lameness in animals, especially cattle, can lead to significant costs and performance losses. There are a variety of diseases and causes that can lead to foot diseases and the resulting lameness. In the field of cattle husbandry, a continuous increase in Dermatis Digitalis (inflammation of the skin of the toes) can be observed, which is also known under the names Mortellaro, Strawberry disease, digital dermatitis, hairy heel warts and Italian foot rot. The intensive animal husbandry with year-round stable housing causes a constant pressure of infection from this contagious disease, the cause and route of infection have not yet been fully researched. The prophylaxis and treatment are mostly carried out through stable hygiene and hoof baths with disinfectant solutions. In the case of acute disease, complex individual animal treatments with antibiotics or special drugs must be carried out. Since claw health and foot health have a significant influence on cow behavior, preventive and nurturing measures to avoid Dermatis digitalis are known in a wide variety of forms. Manually filled and cleaned hoof drive baths with disinfectant solutions that are hazardous to health are a common and time-consuming measure for the treatment and prophylaxis of foot diseases in animals, especially cattle. Furthermore, there are technically complex automatic solutions for improving foot hygiene in animals.

An example is from the US 8,925,493 B2 a hoof bathing system is known in which a hoof bath tub is provided in the ground to be walked on by the animals to be treated, for example in a corridor in front of a milking robot, which is filled with water that is mixed with chemical disinfectants etc. In this case, a bladder for closing the opening provided there is arranged at the downstream end, which bladder is usually inflated, but which is designed to be openable for emptying the hoof bath. This is intended to ensure that organic constituents that are introduced into the bath and that are introduced with the animals' hooves when they are entered or that otherwise fall into the bath are carried away with essentially all of the liquid from time to time. This document also mentions that devices for introducing ozone into the bath for disinfection are possible.

Disadvantages of these bath systems are the considerable hygienic problems due to the entry of organic substances into the bath, so that the disinfecting effect is only given with high doses of disinfectants in the bath and regular fluid exchange. Thus, a considerable consumption of disinfecting chemicals can be determined with a sufficiently hygienic working method, which hardly allows economical operation.

In order to reduce this high consumption of expensive chemicals which are dangerous in terms of health, it has therefore also been proposed to spray the claws or hooves of the animals to be treated by means of nozzles. The U.S. 5,630,379 shows such an arrangement with a flat trough through which the animals must pass, on which light barriers are provided for triggering the nozzles to which the pressurized liquid is to be applied. In this case, after cleaning the hooves with a cleaning fluid, spraying with a treatment solution is proposed in a second bath.

A similar device is from the DE 10 2012 002 930 B3 known, in which the treatment tub are arranged by two mutually parallel steps at a mutual distance according to the foot position of the cattle and by water nozzles arranged in each step, which are aligned in the longitudinal direction of the steps, the claws and feet of the cattle are washed. When a cattle enters the footpath through its forefeet, a motion detector switches on a high-pressure water pump and thus the rear area of the cattle's forefeet and claws is cleaned. After the cattle emerges from the device, the high-pressure pump is switched off again.

In the case of pure use of water in this washing device, an inexpensive cleaning of the claws is achieved, but a supporting disinfecting treatment is not provided.

The DE 20 2014 008 567 U1 describes a device for cleaning hooves or claws by means of a cleaning medium which is part of an automated device for milking, wherein the cleaning medium is preferably a liquid treated by means of electrolysis. For this purpose, the description refers to electrochemically activated water, which by means of sodium chloride dissolved in it is passed through a cell consisting of anode and cathode.

The US 2012/0174872 A1 describes a device and a method for the treatment of animal hooves, in which a mixture of a tub system and a spray system is provided in such a way that the hoof treatment liquid is arranged via spray nozzles along a drift tub so that it passes through a hoof area reaching across to one another without hindrance arranged drip tray so that the hoof treatment fluid collected there can be reused. On the other hand, dirt particles falling into the tub area are guided to a drain by rinsing nozzles exposed to a separate rinsing or cleaning liquid. The aim is to keep the area of the treatment system largely clean in order to ensure the most hygienic application possible.

Furthermore, from the WO 2014/158342 A1 a method for treating animal hooves is known in which a targeted spraying of the hooves by means of a topical, anti-inflammatory solution takes place from the front and back of the claws, the animal stepping on a sensor mat on which load cells are arranged so that only correspondingly assigned nozzles at the time of exposure to the treatment liquid.

With this system, a very targeted and dosed and therefore volume-saving use of the anti-inflammatory solution can be achieved, but the design of the sensor mat with a large number of load cells is likely to be technically susceptible in rough agricultural use.

The object of the present invention is based on the WO 2014/158342 A1 to specify a hoof treatment device and a hoof treatment method in which a dosed and targeted application is possible with low operating costs at the same time.

This object is achieved with a method according to claim 1 or a device according to claim 4.

The fact that water is used as the treatment liquid, into which ozone is injected under pressure and the ozone-containing water is then sprayed specifically on the claw area of the animal when a claw is detected, a disinfecting liquid, namely ozone-containing water, is applied to the foot area ( Claw area) of the animal to be treated is sprayed on. Accordingly, the device has a supply unit with an ozone generator and a water supply in order to provide water containing ozone. In the process, part of the naturally occurring oxygen (O ₂ ) in the ozone generator is converted from the ambient air into ozone (O ₃ ) by means of the high voltage applied there in the resulting electric field. Thus, the method can be carried out technically simply by connecting to a water supply and a power supply using ambient air. A disinfectant that has to be bought and stored separately is therefore not necessary. The ozone generator is preferably supplied with compressed air, which is also mostly available in agricultural operations in order to operate the ozone generator under pressure and to enable the necessary overpressure to inject the ozone-containing air into the water supply. A mixing nozzle, preferably a Venturi nozzle, is used for injecting.

If the ozone-containing water is kept under pressure and ozone is replenished, a higher ozone content can be achieved in the pressurized water. By replenishing ozone or air containing ozone from the ozone generator directly into the pressurized water, the desired ozone content is maintained even if there is a longer pause in water withdrawal. According to the device, this possibility is achieved in that the supply unit has, as a water supply, a water connection with a water line and a pressure vessel for storing the generated ozone-containing water. For this purpose, a lockable supply line preferably leads the ozone-containing air generated from the ozone generator to a mixing nozzle in the water line and / or pressure vessel in order to supply the ozone-containing air generated to the water, the ozone-containing water thus generated being stored in the pressure vessel.

In a further embodiment, the pressure vessel has an average level for the generated ozone-containing water with a gas space located above it, a pressure relief valve being provided in the area of the gas space in the pressure vessel. In this way, compressed air containing ozone, which has been metered into the water pressure tank, is passed through the water absorbed in the pressure tank and finally reaches the upper gas space, in which the pressure relief valve is used to regulate the pressure and release excess residual air.

If a pressure line is provided from the pressure vessel to at least one spray nozzle of the application unit, with at least one metering valve being arranged in the pressure line, the ozone-containing water stored in the pressure vessel is fed directly to the spray nozzle via a pressure line that is as short as possible, with only one metering valve being provided, if necessary dispense the ozone-containing water to be able to. It is therefore advantageous to provide only the metering valve as an adjusting element in the pressure line from the mixing nozzle, in which the ozone-containing air is supplied to the water, to the spray nozzle. The ozone-containing water is extremely aggressive, so that the pressure line and the metering valve next to the pressure vessel must be designed to be ozone-proof. There are therefore no pumps to be provided that are exposed to ozone-containing water.

In a further development of the method, the claw or the animal is optically detected, which triggers a spatially assigned spray nozzle for a specified spraying time, accordingly an economical use of the ozone-containing water is made possible, since these spray nozzles are only triggered for short spraying times when the Claw to be treated and / or the animal is located directly on the spray nozzle. According to the device, this is achieved in that the detection means of the application unit is a reflection light barrier which detects the area at the level of the claw or the entry of the animal in the direction of movement of the animal directly in front of the spray nozzle.

If several spray nozzles are arranged in parallel next to one another over the width of a corridor to be used by the animal and a reflective light barrier and a metering valve that can be triggered by it are provided for each spray nozzle, targeted metering can always be achieved over the width of an aisle by triggering the spray nozzle or the spray nozzles be guaranteed, in which the foot area / claw area of the animal to be treated is detected. This further reduces the unnecessary and ineffective discharge of ozone-containing water, which reduces the operating costs for the claw treatment and at the same time avoids an excessive introduction of moisture in the area of the device.

An exemplary embodiment of the invention is described in detail below with reference to the accompanying drawing.

• 1 einen schematischen Verschaltungsplan einer Vorrichtung zur Klauenbehandlung bei Tieren.

It shows:

• 1 a schematic circuit diagram of a device for treating claws in animals.

In 1 is a circuit diagram for a device for claw treatment in animals, in particular cattle, in which the claws are sprayed with a treatment liquid. The device is essentially divided into a supply unit 1 and an application unit 2 . The application unit 2 is arranged at a suitable place in the stable or the like, where the animals to be treated are forced to walk regularly. This can be, for example, a walk to a milking machine or another place in the stable where the animals are led past individually. The corridor is preferably of such a width that only one animal can pass through at a time.

The supply unit 1 is as close as possible to the application unit 2 arranged, but provided in a protected cupboard or room to protect the components from the harsh influences in the stable and to simplify maintenance and control. The supply unit 1 has an integrated control unit in the exemplary embodiment shown here 3 on that at a power connector 30th is supplied with the usual supply voltage, for example 230 V 50 Hz. Alternatively, the control unit 3 also outside the supply unit 1 be arranged.

Furthermore, the supply unit 1 a water connection 10 with a corresponding water pipe that is connected to the water supply of the agricultural operation, preferably the drinking water supply. Furthermore, the supply unit 1 a compressed air connection 100 to which a conventional compressed air supply from a compressor provided in the stable is connected. A pressure reducer is required if necessary 101 in the compressed air connection line 100 intended. Possibly. is a similar pressure reducer 101 , but for water, directly at the water connection 10 to provide a water pressure of, for example, 2 to 2.5 bar in the supply unit 1 not to be exceeded. The pressure reducer 101 in the compressed air connection line 100 should also reduce the pressure to a maximum pressure of 2.5 bar.

On the compressed air connection line 100 Then a pull generator closes 11 on, which has a supply line 32 from the control unit 3 is supplied with electrical energy. In the ozone generator 11 the oxygen (O ₂ ) in the compressed air is transferred to the generator 11 The high voltage generated is converted into ozone (O ₃ ) with the resulting electric field. The one from the ozone generator 11 in the supply line 13th flowing air is therefore ozone-containing. This ozone-containing air is via the supply line 13th a mixing nozzle or venturi nozzle 15th fed through the main line of the water pipe 10 is led. In the direction of flow of the water in front of the Venturi nozzle 15th is a third valve 18th provided, which as well as a first valve 14th in the supply line 13th if necessary via active lines 31 from the control unit 3 can be controlled.

In the direction of flow behind the venturi nozzle 15th is in the water pipe 10 then contain water mixed with ozone-containing air. The water pipe is now in a pressure vessel 12th who, in a corresponding upright orientation, must be mounted on a wall, for example, as the pressure vessel 12th is only about half loaded with the ozone-containing water, namely exactly up to a level sensor 122 , who via the active line 31 with the control unit 3 connected is. Above the level sensor 122 a gas space is formed 121 out. At the highest point of the pressure vessel 12th is a pressure relief valve 19th provided, with which gas escaping from the ozone-containing water can be discharged into the environment when the pressure rises above a desired working pressure.

Furthermore is from the supply line 13th from the ozone generator 11 to the mixing nozzle 15th in the direction of flow upstream of the first valve 14th a branch into a make-up line 17th provided in which a second valve 16 is arranged. The second valve 16 is also via active line 31 with the control unit 3 connected. The downstream end of the make-up line 17th also leads into the pressure vessel 12th , but here at the lowest point, around that of the ozone generator 11 if necessary via the second valve 16 and make-up line 17th Ozone-containing air supplied over the longest possible effective distance through the water space 120 of the pressure vessel 12th to allow stored ozone-containing water to flow through. At the injection opening of the make-up line 17th into the pressure vessel 12th is an ozone diffuser 171 provided that a fine-bubble distribution of the ozone in the water space 120 causes.

From the pressure vessel 12th leads, also preferably in the deeper area of the container 12th , a feed line 20th from the supply unit 1 to the application unit 2 which is divided into several components arranged in the same way and parallel to one another. Each component has an application valve 21st , behind in the direction of flow a spray nozzle 22nd as well as a reflection light barrier as a detection means 23 on that via active line 31 with the application valve 21st connected is. The reflection light barrier 23 and thus the application valve 21st is via a supply line 32 to the control unit 3 connected to power supply and, if necessary, active line. In the application unit 2 In the exemplary embodiment shown here, five corresponding components are arranged parallel to one another in order to be able to completely cover the width of the aisle. Larger versions with eight, ten or more components arranged in parallel are of course possible. It is also advantageous for every reflective light barrier 23 a small rinsing nozzle for cleaning off any dirt on the reflective light barrier 23 to be assigned, which are activated as required or automatically clocked from time to time.

The method of operation of the device for claw treatment is explained below with reference to the structure just described.

As already described is in the supply unit 1 in the pressure vessel 12th ozone-containing water in the water space 120 in stock. By replenishing ozone-containing air as required via the then activated second valve 16 and the make-up line 17th the ozone content in the pressurized water in the water space 120 in the pressure vessel 12th kept as high as possible.

The water under a pressure of 2 to 2.5 bar in the water space 120 of the pressure vessel 12th is via the spray nozzle 22nd after triggering the assigned photoelectric reflex switch 23 and activating the application valve 21st issued on the assigned ropes. The triggering takes place, for example, by detecting the claw area or foot area of the animal via the reflective light barrier 23 . The application unit is preferred 2 as a bar arranged on the floor so that when the animal climbs over this bar, the animal's foot, which is just above the bar, has one or more of the reflective light barriers 23 triggers and consequently the output of the ozone-containing water via the spray nozzles 22nd he follows. Because the spray nozzles 22nd in the bar-like application unit 2 are arranged in such a way that they spray the ozone-containing water behind the climbing animal in the direction of movement, so the particularly critical area of the hind feet and the toe skin area between the claws is directly affected by the spray from the spray nozzle 22nd met. It is in the control unit 3 a spray duration is stored that is sufficient from the time the reflective light barrier is triggered 3 When the animal moves over it, the ozone-containing water is applied to the foot area.

If now ozone-containing water from the pressure vessel 12th more precisely the water space 120 via the supply line 20th and appropriately activated spray nozzles 22nd is dispensed, the water level in the pressure vessel drops 12th so that the level sensor 122 refilling the pressure vessel 12th to the control unit 3 reports that both the first valve 14th as well as the third valve 18th , namely for supplying compressed air containing ozone to the venturi nozzle 15th as well as fresh water from the water connection 10 to the mixing nozzle 15th activated. The water level reaches in the water space 120 then soon the level sensor again 122 who then both the first valve 14th as well as the third valve 18th locks. The gas room 121 in the pressure vessel 12th ensures a largely uniform pressure in the system for uniform spray characteristics of the spray nozzles 22nd regardless of the water level in the pressure vessel 12th .

If necessary, the second valve 16 from the control unit 3 opened to the make-up line 17th ozone-containing air directly to the water space 120 of the pressure vessel 12th to be able to supply in order to increase the ozone content of the water, or to maintain it in a desired concentration, since ozone (O ₃ ) is very reactive and quickly recombines to normal oxygen (O ₂ ). This replenishment of ozone-containing air can take place continuously or only in the case of longer withdrawal breaks after certain time sequences or also at predetermined time intervals.

List of reference symbols

1

Supply unit

10

Water connection, water pipe

100

Compressed air connection

101

Pressure reducer

11

Ozone generator

12

pressure vessel

120

Water space

121

Gas compartment

122

Level sensor

13th

Supply line

14th

first valve

15th

Mixing nozzle, venturi nozzle

16

second valve

17th

Make-up line

171

Ozone diffuser

18th

third valve

19th

Pressure relief valve

2

Application unit

20th

Pressure line

21st

Dosing or application valve

22nd

Spray nozzle

23

Detection means, reflective light barrier

3

Control unit

30th

Mains connection

31

Effective management

32

supply line

Claims (10)

Method for claw treatment in animals, in particular cattle, in which the claws are sprayed with a treatment liquid, characterized in that - water is used as treatment liquid, into which ozone is injected under pressure, and - the ozone-containing water then when a claw is detected is sprayed specifically on the claw area of the animal. Procedure according to Claim 1 , characterized in that the ozone-containing water is kept under pressure and ozone is replenished. Procedure according to Claim 1 or 2 , characterized in that the claw or the animal is optically detected, whereby a spatially assigned spray nozzle is triggered for a predetermined spray time. Device for claw treatment in animals, in particular cattle, in which the claws are sprayed with a treatment liquid, with a supply unit (1) for providing the treatment liquid and an application unit (2), the at least one spray nozzle (22) and detection means (23) for detection of the animal to be treated, characterized in that the supply unit (1) has an ozone generator (11) and a water supply in order to provide ozone-containing water. Device according to Claim 4 , characterized in that the supply unit (1) has a water connection (10) with a water line as a water supply and a pressure vessel (12) for storing the ozone-containing water produced. Device according to Claim 5 , characterized in that a lockable supply line (13, 17) leads the generated ozone-containing air from the ozone generator (11) to a mixing nozzle (15) in the water line (10) and / or pressure vessel (12) in order to transfer the generated ozone supplying air containing the water to the water, the ozone-containing water thus generated being stored in the pressure vessel (12). Device according to Claim 5 or 6th , characterized in that the pressure vessel (12) has an average level for the generated ozone-containing water with a gas space (121) located above it, an overpressure vent valve (19) being provided in the area of the gas space (121) in the pressure vessel (12). Device according to one of the Claims 4 to 7th , characterized in that a pressure line (20) is provided from the pressure vessel (12) to at least one spray nozzle (22) of the application unit (2), at least one metering valve (21) being arranged in the pressure line (20). Device according to one of the Claims 4 to 8th , characterized in that the detection means of the application unit (2) is a reflection light barrier (23) which detects the area at the level of the claw or the entry of the animal in the direction of movement of the animal immediately in front of the spray nozzle (22). Device according to Claim 8 and 9 , characterized in that several spray nozzles (22) are arranged parallel to one another over the width of a corridor to be used by the animal and a reflective light barrier (23) and a metering valve (21) that can be triggered therefrom are provided for each spray nozzle (22).

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