Perch for Poultry, Sanitization System for a Perch, Method for Sanitizing a Perch, and Joining Piece That Is Suitable for a Perch

Abstract

A poultry perch is effective for ridding poultry of parasites, such as poultry mite. The perch disclosed herein may form part of a sanitation system. The perch has at least one elongated tube with an inner chamber allowing flow through. The tube is provided with a series of access channels, and the inner chamber may be connected to an air pump. The parasite may enter the inner chamber, and it is straightforward to remove the parasite from the perch. Pheromones may be applied to attract the parasite. The tube may be provided with sloping surfaces to prevent droppings from clogging the tube. The parasites are removed by applying a suction via an air pump to the tube. A sanitation system and a method of sanitizing an accommodation for poultry are also disclosed.

Claims

1. A perch for poultry to be placed in a room for accommodating poultry, comprising at least one elongated tube with an inner chamber allowing flow-through, characterized by a series of access channels that run between the outside of the tube and the inner chamber of the tube.

2. The perch according to claim 1, characterized in that the access channels have a smallest cross section in the range from 1 to 10 mm.sup.2 and the access channels are arranged in the tube according to a regular pattern.

3. The perch according to claim 1, characterized in that the wall thickness of the tube is between 0.8 mm and 1.5 mm.

4. The perch according to claim 1, characterized in that the tube is provided with sloping surfaces that face outwards in the upwards direction and in that the access channels are configured as openings arranged in the narrow, sloping surfaces of the tube.

5. The perch according to claim 4, characterized in that the tube has a cross section in the shape of an isosceles triangle with rounded corners, and in that the tube is positioned with the widest side facing upwards.

6. The perch according to claim 1, characterized in that the perch comprises at least two tubes that are positioned in line with one another, the inner chambers of which are connected to one another by a joining piece that extends on the outside of the tubes and joins both tubes together with an airtight seal.

7. The perch according to claim 1, characterized in that a first end of the perch comprises a connecting piece that is configured for connection to the intake connection of an air pump.

8. The perch according to claim 7, characterized in that the connecting piece is provided with a controllable valve.

9. A perch unit for poultry to be placed in a room for accommodating poultry, comprising a series of perches according to claim 1 running parallel to one another and a frame that supports and connects the perches to one another.

10. A sanitization system for a poultry accommodation, comprising at least one perch according to claim 1, characterized in that the connecting piece of each perch is connected to a central discharge line, and in that the central discharge line is connected downstream to an air pump that is configured to create a reduced pressure in the discharge line.

11. The sanitization system according to claim 10, characterized in that the intake side of the air pump is connected to a common outlet connection of a central controllable multiway valve, and in that the inlet connections of the central multiway valve are each connected to a perch.

12. The sanitization system according to claim 10, wherein a main valve is provided on the central discharge line, upstream from the treatment chamber, and wherein an overpressure line is connected to the central discharge line via a return valve so as to create an increased pressure in the perch.

13. The sanitization system according to claim 10, wherein a treatment chamber is placed on the central discharge line for subjecting the poultry mite that have been carried along the discharge line to a treatment.

14. A method for sanitizing an accommodation for poultry that is provided with a sanitization system according to claim 10, characterized in that a reduced pressure is created in the interior of the perch by the pump and the poultry mite present in the interior of the perch is carried along thereby.

15. The method according to claim 14, wherein the end of the perch opposite the connected end is provided with a controllable shut-off valve and pumping is initially effected with the shut-off valve closed and the shut-off valve is subsequently opened.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0027] The invention will the explained in greater detail below by means of a specific embodiment of the invention as is illustrated in the appended figures, which show:

[0028] FIG. 1: an arrangement of several perches according to the invention;

[0029] FIG. 2A: a detail of the structure of a perch at the location of a joining piece;

[0030] FIG. 2B: a longitudinal section through the joining piece from FIG. 2A;

[0031] FIG. 3: a flow diagram of the sanitization system according to the invention;

[0032] FIG. 4: a sectional view of a perch according to an alternative embodiment;

[0033] FIG. 5: a perspective, schematic view of the perch shown in FIG. 4;

[0034] FIG. 6: a sectional view of a perch and a support therefor; and

[0035] FIG. 7: a sectional view of a multiway valve for use with the invention.

DESCRIPTION OF THE INVENTION

[0036] FIG. 1 shows seven perches 1 arranged in parallel that are supported as a group by a number of transverse profiles 3. The perch is of modular construction, constructed from a series of consecutive tubes, and typically has a total length of 40 metres. The assembly 4 forms for example an uppermost storey in a conventional aviary system or colony system in a poultry shed. A first end of the perches is connected to a central discharge line 7 that leads to a main valve 9. After this main valve 9, the line 7 continues on to a treatment device (not shown) for treating poultry mite and an air pump. Each first end of a perch is additionally provided with a remote-controlled valve 11. The second ends of the perches 5 connect to an end line 13 with an end valve 15. Incidentally, it is possible for the main valve 9 to be omitted.

[0037] FIG. 2A shows a detail of the structure of a perch 1 from FIG. 1, namely the connection of two consecutive ends of adjacent tubes 21 and 22 by means of a tubular joining piece 24, which is shown as being see-through for the sake of clarity of the drawing but which in reality is not transparent. The tubular joining piece 24 comprises opposite end segments 34 which fit onto the ends of the adjacent tubes 21 and 22 in a clamping manner, forming a substantially airtight seal. The joining piece comprises a middle segment 36 between the end segments 34 which determines a distance between the reciprocal ends of the adjacent tubes 21, 22, for which the inside of the middle segment 36 is provided with a stop profile. The edges 26 of the joining piece have a tapering profile, which narrows in the direction of a relatively small entrance 28 into the access channel. The access channel runs from the entrance 28 into the inner chamber 30 of the joining piece, which is in open communication with the inner chamber 32 of the tubes 21 and 22. The two entrances 28 into the access channel shown on the top side are bounded by a sleeve 40. The joining piece 24 is thus provided with entrances 28 into an access channel on multiple sides. Poultry mite present on the perch will, in the situation shown, be tempted to make use of the entrances 28 into the access channel in order to hide in the dark interior of the perch 1.

[0038] FIG. 2B shows a longitudinal section through the joining piece shown in FIG. 2A, wherein identical components are denoted by the same reference numbers. The inner wall 42 of the joining part 24 is made thicker in the middle segment 36 so as to form a stop body 44, against which the reciprocal ends (not shown) of the adjacent tubes butt. The length of the stop body 44 thus determines the distance between the two reciprocal ends of the adjacent tubes which are connected by the joining part.

[0039] An elongated groove 38 is present as the access channel between the two entrances 28, which are surrounded by sleeve 40. When the respective ends of connected tubes are inserted into the respective end segments 34, the groove 38 will be in open communication with the inner chamber 30 of the joining piece 24 at the location of the middle segment 36, and thus the access channel 38 will run from the outside of the joining piece to an inner chamber of the joining piece. The channel 38 thus allows an airflow between the outside of a perch and the inner chamber of a perch.

[0040] The underside of the joining piece is provided with a profile 48 combined with a small steel tube 46 that acts as a reinforcing structure for the joining piece. The small tube 46 bridges the middle segment 36 and thus forms a rigid bridging part between the two ends of tubes that are connected to the two respective end segments 34. This reinforcing structure makes it possible for the rest of the joining piece to be formed from an elastomer which is advantageous for contacting tubes in a clamping manner, while the joining piece as a whole provides sufficient rigidity and strength as a component of the perch.

[0041] FIG. 3 shows a flow diagram of the sanitization system 50 according to the invention. A first part 52 of the sanitization system is arranged in a poultry shed and consists of seven perches 1 which are connected to a central discharge line 11 by a first end. Insofar as they correspond to the representation in FIG. 1, identical components are illustrated with the same reference numbers, including the end line 13 with end valve 15, and the valves 11 of the perches. The second end of each perch 1 that is connected to the end line 13 is additionally provided with a non-return valve 56, which allows only an outflow of air from the end line 13 into the perch 1 and thus prevents a reverse airflow from the perch 1 to the end line 13.

[0042] Inside the second part 54 of the sanitization system, which is optionally arranged outside the poultry shed, the discharge line 7 leads, after passing main valve 9, through a cyclone filter 58, which also acts as a treatment chamber for killing poultry mite. To this end, the cyclone 58 is provided with features for subjecting the poultry mite to a treatment, such as exposure to hot air, hot water, electricity, UV radiation, water and soap or pesticides, or a combination thereof. Depending on the required capacity of the sanitization system, additional cyclones may be arranged in series with cyclone 58, which may or may not be provided with the abovementioned features.

[0043] The discharge line 7 then leads to a pump 60 for creating a reduced pressure in the discharge line 7. The pump 60 creates an extracting airflow from the inside of a selected perch 1, the valve 11 of which is opened, to the treatment chamber 58 via the central discharge line 7. Behind the pump 60, the pumped-out air is passed into the outside air via end 70 of line 7. When applying a reduced pressure in the sanitization system, the non-return valves 56 close those perches, the valves 11 at the first end of which are not open, off at the other, second end too, such that the reduced pressure can only be present in a selected perch.

[0044] Downstream of the pump 60, an overpressure line 62 is provided which is connected to the return valve 64, so as to be able to create a reverse, expelling airflow in the first part of the sanitization system 52 with perches. By closing the main valve 9 and the first auxiliary valve 66, and opening second auxiliary valve 68, air is drawn in from the end 70 in order to purge the sanitization system using pump 60 via return valve 64.

[0045] The above sanitization system provides an adequate and practical means for the periodic, and preferably daily, removal of poultry mite from perches.

[0046] The joining pieces 24 between the tubes 21, 22 of a perch 1 provide a hiding place for poultry mite during (day)light hours in the poultry shed. The pump 60 is activated at least once a day, whereby a reduced pressure is created in the inner chamber of the perch so that as many mites as possible in the vicinity of the entrances 28 into the access channels are sucked into the inner chamber, where a considerable number of poultry mites are already hiding. By then opening the end valve 15, a stronger extracting airflow can be created, by means of which the poultry mite are carried into the treatment chamber, in this case cyclone 58, via the discharge line 7, where they are killed. After these actions, the majority of poultry mite have been removed from the perches, and the health risk to the poultry has been greatly reduced.

[0047] It is furthermore possible within this system for the removal of poultry mite to be carried out per individual perch, and for this to be carried out on a timer and to be automated.

[0048] Once all of the perches have been sanitized, a brief, sharp expelling airflow can be sent through each perch by the pump 60 via overpressure line 62 and by opening return valve 64. This step is intended to prevent the access channels 38 from becoming clogged or blocked in any way by sticky substances such as poultry droppings. Such a system may be self-cleaning, and thus requires little maintenance. The non-return valves 56 ensure that the expelling air flow escapes only via the access channels 38, and thus that a sharp, effective airflow is obtained so as to purge the access channels 38.

[0049] FIG. 4 shows a sectional view of an alternative embodiment of a tube of a perch according to the invention. The tube 75 has a cross section in the shape of an isosceles triangle, the long side 76 of which faces upwards. The corners are rounded. In this way, a comfortable perching surface for the poultry is formed. The tube 75 is made of galvanized steel sheet, for example by rolling and welding. Openings 78, which serve as access channels, are arranged at regular distances from one another in the sloping, downward facing surfaces 77 of the profile. FIG. 5 shows the same profile in perspective. Incidentally, for the poultry's comfort, it is preferable for the width of the upper surface of the tube to be at least 30 mm.

[0050] FIG. 6 shows a sectional view of a tube 75, which is placed on a supporting plate 90 belonging to a frame. The supporting plate 90, which is preferably made of metal, is provided with an opening 91 in the shape of the tube 75, but of larger size so that a gap 92 is formed between the tube 75 and the supporting plate 90. However, the tube 75 rests on two tongues 93 arranged in the opening 91. The gap prevents the poultry mite from reaching the plate easily, so that they remain instead on the tube and go through the access channels 76 to seek refuge in the interior of the tube 75. The supporting plate 90 is additionally provided with a number of openings 94 for securing the supporting plate to the frame of the perch unit for the poultry.

[0051] FIG. 7 shows a sectional view of an exemplary embodiment of a central controllable multiway valve 80. This multiway valve 80 comprises an elongated substantially rectangular housing 81, which is provided with an extension 82 at both ends. The housing 81 is provided on a first side with four connectors 83 to which the connections to the perches can be connected. A connector 84 for the pump is arranged on the opposite side. This connector leads to a chamber 85 of the housing 81. A valve body 86 is arranged in the housing 81, which valve body is movable in the longitudinal direction of the housing 81. An opening 87 is arranged in the valve body 86, which will connect the chamber 85 to the chosen connector 83. The valve body 86 can be driven in the direction of movement by a drive element (not shown in the drawing), such as an electromagnet or another linear drive member. It will be clear that, instead of the multiway valve shown, other types of multiway valves may be used.