NL1022288C2 - Animal slaughter method, especially for poultry, involves simultaneously unloading animals from containers at stations at different points along conveyor - Google Patents

Abstract

Animals to be slaughtered are simultaneously unloaded from containers (4) at several unloading stations (20a-20c) at different locations along a conveyor (30) used to deliver them to a killing step. A method for slaughtering animals, especially poultry, in an abattoir comprises the following steps: (1) supplying the animals in multi-compartment containers; (2) unloading the animals from each container at an unloading station; (3) securing each animal to a conveyor; and (4) killing the animal. Several unloading stations are located along the conveyor and during step (b) animals are simultaneously unloaded from containers at different stations.

Description

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Title: Method and device for processing slaughter animals.

The invention relates to a method for processing slaughtered animals, in particular birds, in a slaughterhouse, comprising the steps of: supplying the slaughtered animals in containers, wherein each container comprises several compartments; unloading the slaughtered animals from one of the containers at a discharge station; 10 coupling each slaughtered animal to a conveyor; and slaughter of the animals for slaughter. The invention also relates to a device for processing slaughtered animals.

The invention has for its object to utilize the full capacity of a conveyor leading to a slaughtering device when processing slaughtered animals in a slaughterhouse.

Furthermore, when processing slaughtered animals in a slaughterhouse, it is a known method to anesthetize the slaughtered animals prior to slaughtering. Traditionally, this anesthetic takes place by passing an electric current with predetermined characteristics through the body or a part of the body of the slaughtered animal.

Alternatively, the anesthetic can take place by placing the animals for slaughter in an atmosphere containing an anesthetic gas, such as argon, or with an anesthetic gas mixture, such as, for example, a mixture of air or oxygen, and argon or carbon dioxide.

Thereby, the duration of action of the gas or gas mixture and / or the concentration of the constituent gases in the gas mixture can be varied in order not only to cause anesthesia, but subsequently also to kill the slaughter animals.

In the above-described processing by means of gas stunning 30, essentially two different approaches are known, both of which are described for poultry in EP-A-0 680 259. In a first approach, the slaughter animals, while they are in a container, are passed through an anesthetic device with the aid of a mechanical transport means, to subsequently be released from the container and to be slaughtered one by one. In a second approach, the slaughtered animals are transported through a stunning device one by one by means of a mechanical transport means before being slaughtered 102 22 53 2. In this second approach, the animals for slaughter are discharged from the usual container with which they have been taken to the slaughterhouse before being passed through the stunning apparatus.

In both the first and the second known approach, the animals for slaughter are anesthetized and possibly killed in the anesthetic device in such a way that the oxygen supply to, in particular, muscles in the body of the slaughtered animal stops, on the one hand, because the blood transporting the oxygen into the body does not contain oxygen absorbs more from the atmosphere present in the anesthetic, and on the other hand because the blood circulation stops because of heart failure.

As soon as the oxygen supply to the muscles stops, a stiffening of the muscles starts, which increases with the passage of time. This complicates the subsequent bleeding of the slaughtered animals and, in the case of poultry, the deprivation thereof. It is therefore important to shorten the length of time that elapses between the stunning and subsequent processing of the animals for slaughter.

In the above-mentioned first approach the problem arises in this connection that the time between the stunning and the subsequent processing for the different slaughter animals is different.

The animals for slaughter are, after being substantially simultaneously stunned in a container, all discharged from the container substantially simultaneously, and subsequently further processed one by one. Thus, said period of time is considerably shorter for the first further processed slaughter animal 25 than for the last further processed slaughter animal, which is undesirable.

In the above-mentioned second approach, which is usually followed not only for gas stunning, but also for electrical stunning, the problem arises that the slaughter animals cannot be handled easily during and after their release from the container, since they are opposed to the treatment they undergo. On the one hand, this is opposed by the slaughter animals refusing to leave the container by clinging to or bracing themselves in the container. On the other hand, this precludes unwanted movements of body parts of the slaughtered animals when handling the slaughtered animals after 3 people have left the container.

Yet another problem occurs in the slaughter of slaughter animals in a religious manner ("kosher" or "Hallal"). Namely, anesthetizing of the slaughtered animals as is customary for industrial, non-religious slaughtering methods leads to an anesthetic condition which is necessarily so deep that the slaughtered animals are transported between a stunning station during the time required for transporting the slaughtered animals. and a slaughtering station, will certainly remain anesthetized. However, such a deep anesthetic is unacceptable in religious slaughter, which is why anesthesia is not applied to religious slaughter on an industrial scale, or is only applied to manual slaughter.

The invention has for its object to utilize the full capacity of a conveyor leading to a slaughtering device when processing slaughtered animals in a slaughterhouse, and in addition to solving one or more of the aforementioned problems, and for this purpose firstly provides a method of the above-mentioned type, wherein several unloading stations are provided along the path of the conveyor, wherein when unloading the slaughter animals from one of the containers, slaughter animals are simultaneously unloaded from several containers located in different unloading stations.

Preferably, each of said containers is placed in a separate container

Unloading station at least partially unloaded.

Preferably, each container is passed along different unloading stations, and one or more subsequent compartments of said container are unloaded in each unloading station.

Preferably, when the slaughter animals are unloaded at a unloading station, slaughter animals are unloaded simultaneously from a plurality, in particular from all compartments, of one of the containers.

The slaughtered animals are preferably buffered after being released from a container and prior to being coupled to a conveyor.

Preferably, the slaughtered animals are anesthetized prior to the unloading of the slaughtered animals from a container 1124 in a discharge station, whereby they are brought into a first state of anesthesia in which they are unconscious, and the oxygen supply to the muscles of the slaughtered animals is substantially remains intact. The first state of anesthesia is in particular at least so deep that the animals for slaughter do not experience any pain or discomfort, as a result of which they can easily be manipulated, and do not cling to or brace themselves in the container of their own accord, or make other undesired movements. This is particularly advantageous when releasing the animals for slaughter from the container, and for subsequent treatments for the animals for slaughter, comprising optionally arranging or positioning the animals for slaughter, optionally coupling each animal for slaughter with a conveyor and slaughtering the animal for slaughter, for example by cutting one or more arteries or veins, and subsequently bleeding the slaughtered animal.

On the other hand, the anesthetic is so shallow that the oxygen supply to the muscles of the slaughtered animals remains substantially intact, thereby preventing the muscles from already stiffening during the first state of anesthesia and bleeding and, in the case of poultry, de-staging thereof becomes more difficult. The fact that the slaughtered animals are mainly unloaded from their container simultaneously and then further processed one by one, no longer leads to a difference in muscle stiffening in post-release treatments.

Allowing the first state of anesthesia to continue for as long as possible, in particular up to and including slaughter of the animals for slaughter by opening one or more arteries or veins thereof, offers the important advantage that prior to slaughter the oxygen supply to the muscles of the slaughtered animals remain substantially intact and therefore no stiffening of these muscles can yet occur. This facilitates bleeding and, in the case of poultry, depleting thereof.

In a preferred embodiment of the method according to the invention thereof, in particular after the slaughter animals are released from the containers, the slaughtered animals, after being brought into the first anesthetic state, are brought into a second anesthetic state prior to slaughtering. deeper than the first state of anesthesia. In particular, the slaughtered animals are killed when they are brought into the second state of anesthesia. In the second state of anesthesia, in contrast to the first state of anesthesia, there will be a stagnation of the oxygen supply to the muscles of the slaughtered animals, so that a stiffening of the muscles will occur. Furthermore, by bringing about the second state of anesthesia it is prevented that the slaughter animals come to consciousness prematurely during the following operations. The triggering of the second state of anesthesia after the container has been unloaded has the advantage that the animals for slaughter no longer need to be stunned simultaneously, but the anesthetic treatment can be subjected substantially sequentially, so that the time between triggering the second state of anesthesia and subsequent operations on the relevant slaughter animal is substantially the same for all slaughter animals.

In a preferred embodiment, the first anesthetic state and / or second anesthetic state is triggered by a gas anesthetic, the anesthetic taking place in one or more chambers, each of which maintains a gas atmosphere with a predetermined composition. Thus, for example, one space in which there is a gas atmosphere which causes the first state of anesthesia in the slaughtered animals can be used to successively anesthetize the slaughtered animals in the container, to unload the slaughtered animals from the containers, to position the slaughtered animals automatically and to transport them with a conveyor. and slaughter the animals for slaughter. The single space can optionally be subdivided into compartments or chambers for better control of the composition of the gas atmosphere, or for easily carrying out maintenance and repair to and cleaning of the various equipment to be used for the described operations. The automatic positioning and suspension of poultry on a carrier of a conveyor is known per se.

Preferably, the gas anesthesia of the slaughtered animal is triggered by anoxia, in particular by bringing the slaughtered animal into a 6 atmosphere with at most 2 vol.% Oxygen for a sufficient time to reach the first state of anesthesia.

This percentage of oxygen can be achieved, for example, in an atmosphere with at most 10 vol.% Air, the remaining part of the atmosphere consisting of one or more of argon, nitrogen and carbon dioxide gases, for example about 30 vol.% Carbon dioxide and 60 vol. % argon. With anoxia a rapid loss of posture of the slaughtered animal is achieved, with strong convulsions occurring.

In another preferred embodiment the gas anesthetic of the slaughtered animal is triggered by hypercapnic hypoxia, for example by bringing the slaughtered animal into a gas atmosphere with at least 60% by volume of carbon dioxide for a sufficient time to reach the first state of anesthetic. With hypercapnic hypoxia a rapid loss of posture of the slaughtered animal is achieved. Strong convulsions occur.

In a further preferred embodiment the gas anesthetic of the slaughtered animal is triggered by hypercapnic hyperoxygenation, for example by bringing the slaughtered animal into a gas atmosphere with at least 25% by volume of oxygen and at least 20% by volume of carbon dioxide for a sufficient time to reach the first anesthetic condition. With hypercapnic hyperoxygenation a rapid loss of posture of the slaughtered animal is achieved, with strong convulsions occurring.

In a preferred method, in which advantageously use can be made of different chambers, each having its own gas atmosphere, the gas anesthetic of the slaughtered animal is induced in an induction phase by a gas mixture of 30% oxygen by volume, 40% carbon dioxide by volume and 30% by volume. % nitrogen by volume, and is produced in a final phase by a gas mixture of 80% carbon dioxide with 5-15% oxygen by volume. Here, the first anesthetic state is reached in the induction phase, and the second anesthetic state is reached in the final phase. The induction phase is very gradual, with the slaughtered animal barely moving, if at all.

In another preferred method, in which to achieve an optimum processing speed use can be made of different chambers, each with their own gas atmosphere, the Ί 0 c; 7 gas anesthesia of the slaughtered animal brought about by the steps of: bringing the slaughtered animal for about 20 seconds into a first gas atmosphere comprising approximately 20% by volume of carbon dioxide and approximately 20% by volume of oxygen; bringing the slaughtered animal for approximately 50 seconds into a second gas atmosphere comprising approximately 40 vol.% carbon dioxide and approximately 20 vol.% oxygen; and bringing the slaughtered animal for about 30 seconds into a third gas atmosphere comprising about 50 volume% carbon dioxide and about 20 volume% oxygen. Hereby the first anesthetic state is reached in the first gas atmosphere, and the second anesthetic state is reached in the second gas atmosphere. The slaughtered animal is hereby stunned very gradually, with little or no movement.

In another preferred embodiment of the method according to the invention, the first and / or second anesthetic condition is triggered by an electrical anesthetic.

The electrical anesthetic of the slaughtered animal is preferably generated with an alternating current with a frequency of at least 20 Hz and at most 2.5 kHz, advantageously using a normal, usual mains frequency. However, the higher the frequency, the less damage, such as bleeding, to the slaughtered animal will occur. If the frequency is 75-125 Hz, only minimal physiological changes of the slaughtered animal occur. At frequencies between 450-550 Hz, negative consequences of an electrical anesthetic are already largely prevented. In another preferred embodiment of the method according to the invention, the first and / or the second anesthetic condition is triggered by an electrical anesthetic or by exposing each slaughter animal or part thereof to high-frequency radiation, in particular high-frequency electromagnetic radiation. In this way an anesthetic can be achieved which is based on a temperature rise of the central nervous system. In particular, anesthesia occurs at a temperature of approximately 45 ° C.

In a first preferred method, a frequency of 900-1000 MHz is applied, with which in the case of poultry a strong warming of the neck and the wing ends is obtained in the case of full body irradiation.

'Jr. · 8

In a following preferred method, a frequency of 2400-2500 MHz, in particular 2450 MHz, is used. Such a frequency is most optimal, given the properties of the radiation: round shapes with a radius of 0.8 to 5 cm concentrate the energy in the center thereof. An example of such a shape is the head of poultry.

A device for processing slaughtered animals, in particular birds, in a slaughterhouse, wherein the slaughtered animals are supplied in containers, and each container has several compartments, comprises: a release device for releasing the slaughtered animals from the containers; transport means for transporting the containers along the unloading device; a slaughtering device disposed downstream of the unloading device; and a conveyor for coupling the unloaded slaughter animals thereto and transporting the slaughtered animals from the unloading device to the slaughtering device.

According to the invention, the unloading device comprises a number of unloading stations which are placed along the path of the conveyor, and which are each adapted to at least partially unload one of the containers, and wherein the unloading device is adapted to simultaneously slaughter animals of several, unloading containers located at the unloading stations.

In a preferred embodiment, the unloading device comprises a number of unloading stations, each of which is adapted to unload one or more following compartments of one of the containers transported along the unloading stations by the transport means.

In a preferred embodiment, the unloading device is adapted to unload animals for slaughter from several, in particular all, compartments of one of the containers at the same time.

In a preferred embodiment, the unloading device comprises a buffer device, the buffer device preferably comprising a controlled conveyor.

In a preferred embodiment, the device according to the invention comprises an anesthetic device for anesthetizing the slaughter animals in containers, with transporting means for transporting the containers through the anesthetic device, the anesthetic device upstream of said device the releasing device is arranged, and wherein the animals for slaughter are brought into the anesthetic device in a first anesthetic state in which they are unconscious, and the oxygen supply to the muscles of the animals for slaughter remains substantially intact. The aspects and advantages of such a design have already been discussed above.

By choosing the nature of the anesthetic the releasing device can advantageously be arranged downstream of the anesthetic device.

In a further preferred embodiment the anesthetic device comprises at least one anesthetic space, the releasing device being arranged in the at least one anesthetic space. This effectively prevents the animals for slaughter from waking up from their state of anesthesia during the release of the animals for slaughter from the containers. The animals for slaughter are thus certainly not aware of the events during the release, whereby stress reactions of the animals for slaughter are prevented.

In a preferred embodiment, the device according to the invention further comprises a second anesthetic device arranged downstream of the unloading device for anesthetizing the released slaughter animals, with second transport means for transporting the slaughter animals, wherein the slaughter animals are brought into a second anesthetic condition which is deeper than the first state of anesthesia. In particular, the second transporting means are arranged to transport the respective slaughtered animals substantially sequentially, so that for each slaughtered animal the time between the onset of the second state of anesthesia and the slaughtering can be substantially equal, so that a uniform high quality of the slaughter products can be achieved.

The unloading device comprises tilting means for tilting containers in a simple and advantageous manner.

In an advantageous alternative embodiment, the unloading device comprises expulsion means for moving the slaughter animals to an open side of the container. Slaughter animals in the first state of anesthesia can simply be moved in the container with the expulsion means to enable a person to pick up the slaughter animals easily, for example for hanging the slaughter animals on hooks. It is prevented that the person has to pick up live, resisting animals for slaughter, or that the person has to assume an uncomfortable working position to pick up the animals for slaughter deep in the container.

The container preferably comprises a wall formed by bars, wherein the expulsion means can be moved from the outside of the container between the bars into the container. If the container comprises several compartments, the expulsion means 10 are preferably effective per compartment.

In a preferred embodiment, the expulsion means comprise a series of expulsion elements, which extend at a end to be introduced into the container over a part of the height of the container or a compartment thereof. In a simple, inexpensive construction, the expulsion elements are substantially T-shaped or plate-shaped.

In a preferred embodiment the unloading device comprises a substantially horizontal belt conveyor with an endless conveyor belt, of which belt conveyor at least a portion is intended to be introduced into the container near a bottom thereof, or near a bottom of a compartment of the container. At a sufficiently small height of the part of the belt conveyor located in the container, conscious or dead slaughter animals in the first or second anesthetic state slide easily onto the conveyor belt to be brought out of the container.

The conveyor belt is preferably driven such that it is displaced over a predetermined distance when introducing said part of the belt conveyor into the container. In the case of slaughtered or dead animals for slaughter in a first or second anesthetic state, these are easily removed from the container and buffered on the conveyor belt before being further transported and processed.

In the following, the invention is explained in detail with reference to the accompanying drawing, in which non-limiting exemplary embodiments are shown, and in which: Fig. 1 shows a perspective view of a first arrangement for processing poultry according to the invention; Fig. 1a schematically illustrates in cross-section the operation of a discharge station in the arrangement of Fig. 1; Fig. 1b shows another unloading station in perspective; Fig. 1c shows another unloading station in perspective; Fig. Id shows another unloading station in perspective; Fig. 1e shows a unloading station in perspective again; Fig. 1f shows another unloading station in perspective; Fig. 1g shows another unloading station in perspective; Fig. 1h shows another unloading station in perspective; Fig. 1i shows another unloading station in perspective; Fig. Ij shows another unloading station in perspective; Fig. 2 shows a perspective view of a second arrangement for processing poultry according to the invention; Fig. 3 shows in side view, partly in cross-section, a part of the arrangement of Fig. 2; Fig. 4 shows a plan view, partly in cross-section, of the arrangement according to Fig. 2; Fig. 5 shows in cross-section a part of the arrangement of Fig. 2; Fig. 6 shows in side view, partly in cross-section, another part of the arrangement of Fig. 2.

Fig. 7 shows a perspective view of a third arrangement for processing poultry according to the invention;

In the various figures, the same reference numerals refer to the same items, or items with the same function.

FIG. 1 shows a part of a slaughterhouse in which poultry, in particular turkeys, but also for example chickens, ducks, geese or the like, is processed. A conveyor 2, such as a belt conveyor or a conveyor with another means of transport that can suitably engage with containers 4 to be transported along the path of the conveyor 2 in the direction of arrow 3, is supported on supporting beams 6 at some height above a floor from the 35 slaughterhouse. The conveyor 2 can comprise a single conveying means, but can also comprise different conveying means which can be operated independently of each other and which move a container 4 successively along the path of the conveyor 2.

In the path of the conveyor 2 there is a gas numbing device 8, which in the shown embodiment comprises an enclosure with a number of wall parts through which the conveyor 2 leads. The gas anesthetic device 8 is provided on two opposite sides with a wall part 12 which is displaceable along a rail 10, with which an opening and closing access to resp. output from the gas anesthetic device 8. The gas-extinguishing device 8 is provided with a discharge line 14 which is in open communication with the interior of the enclosure and which is arranged on the top wall of the enclosure, and with a supply pipe 16 which is in open communication with the interior of the enclosure and which is arranged on or near the bottom wall of the enclosure. By introducing a stunning gas or gas mixture into the enclosure via the supply line 16, an atmosphere is created therein for bringing the poultry present in a container 4 into a first anesthetic state (in which the poultry is unconscious, and the oxygen supply to the poultry muscles remains substantially intact), when the container 4 is inside the enclosure for at least a predetermined time. The anesthetic gas or gas mixture is led through the enclosure substantially in countercurrent (relative to the conveying direction 3 of the conveyor 2), from the supply line 16 to the discharge line 14, although the flow direction may also be reversed as desired. The enclosure is dimensioned in such a way that there can be at most three containers 4 therein, the container 4 that first entered the gas stunning device 8 also leaving it first ("First In First Out (FIFO) principle"). a side wall of the enclosure comprises windows 18 for observing the effect of the anesthetic gas or gas mixture on the poultry.

Each container 4 comprises three compartments 4a, 4b and 4c located at different heights. Incidentally, this is not essential for the present invention, according to which containers with a smaller or larger number of stacked compartments can also be processed.

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Three unloading stations 20a, 20b, 20c are arranged in the path of the conveyor 2 for unloading the poultry from the containers 4. The number of unloading stations is equal to the number of compartments of the containers to be processed, so that a different number of unloading stations belongs to a different number of compartments than that shown in Fig. 1. Each unloading station 20a, 20b, 20c may comprise retaining means (not shown) in order to fix the location of a container 4 relative to the relevant unloading station. On the other hand, the conveying means of the conveyor 2 can be controllable, possibly in combination with one or more stops to be placed in and out of the path of the container, that the container is positioned with sufficient accuracy in a discharge station 20a, 20b or 20c.

As appears in more detail from Fig. 1a, the unloading station 20a 15 is provided with an expulsion member 22, such as a movable wall or a collection of elements arranged in a plane, which expulsion member 22 can be introduced into the container 4 and by means of one or more driving members 24, such as jacks 26 with connecting rods 28, can be moved between the first position indicated by solid lines and the second position indicated by broken lines. The container 4 can for instance comprise a wall formed by bars, wherein the expulsion member 22 can be moved from the outside of the container 4 between the bars into the container 4. Preferably, the drive members 24 are arranged such that the expulsion member 22 position to be determined by an operator, as desired, in or between the first and second position.

The expulsion member 22 of the unloading station 20a is active in the lower compartment 4a of a container 4. Similarly, expulsion members 22 of the unloading stations 20b and 20c are active in the middle compartment 4b, respectively. the upper compartment 4c of a container.

Finally, fig. 1 shows a schematically indicated overhead conveyor 30 in which trolleys 35 are moved along a rail 35 to which hooks 32 are attached in a manner known per se. Along the path of the overhead conveyor 30, respective platforms 34a, 34b and 34c are situated at the location of the unloading stations 20a, 14 20b and 20c, each with a predetermined height.

The operation of the arrangement according to Figs. 1 and 1a is as follows. On the left-hand side of Fig. 1, containers 4 with live, conscious poultry are fed into the stunning apparatus 8 by means of the conveyor 2, to which an access opening has been created by sliding the wall 12 along the rail 10 to the side. The poultry in the anesthetic device 8 is then brought into the first anesthetic state. Each container 4 with the poultry brought into the first anesthetic state is then successively transported to the unloading stations 20a, 20b and 20c with the aid of the conveyor and placed there. At the unloading station 20a the lower compartment 4a of the container 4 is opened, and at the unloading stations 20b and 20c the middle compartment 4b and upper compartment 4c respectively. At the various unloading stations 20a, 20b and 20c there are respective unloaders 36a, 36b and 36c, the height of the respective platforms 34a, 34b and 34c being chosen such that each unloader can open the opened compartment at a good working height, for example chest height. has itself. Each looser 36a, 36b or 36c operates in a suitable manner, for example with one or more foot pedals, the drive members 24 of the expulsion member 22 for displacing it in the direction of the opening of the relevant container compartment facing it. unconscious poultry. It is, of course, also possible for the drive members 24 to drive the drive-out member 22 autonomously, with a predetermined speed pattern, without the release having to influence this. The poultry thus located near the compartment opening can be grasped very easily and efficiently by the looser and, by turning over, can be hung on a passing free hook 32. The hooks 32 hang at a good working height because the height of the overhead conveyor 30 follows the height of the container compartment to be unloaded at each unloading station. When the upper compartment 4c of the container located there has been emptied in unloading station 20c (wherein the lower compartment 4a and the middle compartment 4b of the same container have already been emptied earlier in the unloading stations 20a and 20b, respectively) and in the unloading station 20b the middle compartment compartment 4b of the container located there has been emptied (with the lower compartment 4a of the same container already being emptied into the unloading station 20a), the container that is in the unloading station 20c 5 can be further transported with the aid of the conveyor 2, and the container located in the unloading station 20b can be transported to the unloading station 20c. Similarly, the container located in the unloading station 20a can be moved to the unloading station 20b as soon as this is released. It will be clear that an optimum working situation is created for the unloaders if the first anesthetic condition persists at least until the unloader 36c has emptied the upper compartment 4c of the container located there.

The overhead conveyor 30 transports the poultry suspended from the hooks 32 to a subsequent processing station, such as a bleeding station in which one or more blood vessels of the poultry are opened, and the poultry bleeds out.

FIG. 1b shows a discharge station 100 which is arranged downstream with respect to a gas stunning device 8. The unloading station comprises a roller conveyor 102, over which a container 4 filled with stunned birds 104 can be advanced in the direction of arrow 106, either by hand or by driving rollers 108 of the roller conveyor 102, or by others, along the track. means, such as a carrier, disposed of container 4, not shown. The roller conveyor 102 is provided with a stopper 110 to be brought in and out of the path of the container 4 for stopping the container 4 at a predetermined location in the unloading station 100. An expulsion member 112 comprises a series of parallel, substantially rectangular plates 114, each of which is attached to a support 116 at one end thereof. The carrier 116 can be steered in a controllable manner in the directions of double arrow 120 by means of a pair of jacks 118, which may be of an electrical, pneumatic or hydraulic type, the plates 114 passing between bars on one side of the container 4 move in a compartment 121 of the container 4. The container 4 can be opened per compartment in a manner not further shown on an opening side opposite to the side provided with bars, and the free ends of the plates 114 can push birds 104 located in the compartment on the opening side out of the container 4. To catch the birds 104 during their removal from the container 4, a belt conveyor 124 is arranged on the opening side of the container 4 with a conveyor belt 128 moving in the direction of arrow 126, on which the birds 104 end up from the container 4, and be discharged for further processing, such as possibly further stunning or killing, positioning, hanging, opening a blood vessel, bleeding, and the like.

The roller conveyor 102 can be moved up and down in the directions of double arrow 130 relative to the expulsion member 112 and the belt conveyor 124 with the aid of driving means of any known type, not shown in more detail, in order to remove the birds 104 from the following compartments able to unload. It is of course also possible to cause the expulsion member 112 and the belt conveyor 124 to move in the directions of the double arrow 130 relative to the roller conveyor 102 for unloading other compartments.

The arrangement shown in Fig. 1c essentially corresponds to that of Fig. 1b, with the exception of the belt conveyor 132 used. The conveyor belt 134 of the belt conveyor 132 is guided along rollers 136, 138 such that a portion of the conveyor belt 134 can be brought into a compartment 121 of the container 4, more particularly along the bottom of the compartment 121, over a part of the depth of the compartment.

This movement can be accomplished by moving the belt conveyor 132 as a whole in the direction of arrow 140, or by moving the roller 136 of the belt conveyor 132 in the plane of the conveyor belt 134 in the direction of the arrow 140 relative to an otherwise fixedly arranged frame of the belt conveyor 132. A sufficient free length of the conveyor belt 134 must be available here, wherein the conveyor belt 134 can for instance be kept under tension with the aid of the roller 138, which is also movable for this purpose. is carried out. The expulsion member 112 slides the birds 104 onto the portion of the conveyor belt 134 located in the compartment 121, which conveys the birds 104 for further processing.

FIG. Id shows a similar arrangement as fig. 1c. In Fig. 1d, however, the conveyor belt 134a is provided with perforations 135, from which a gas or gas mixture flows to induce the first anesthetic state of the birds 104, or to induce the second anesthetic state if the first anesthetic state of the birds 104 is already in the gas extinguishing device 8 was achieved. The gas or gas mixture is, for example, spread between the forward and return portions of the conveyor belt 134a to escape through the perforations 135 of the conveyor belt 134a. The birds 104 located in the immediate vicinity of, or on, the conveyor belt 134a, which inhale the gas or gas mixture, get into the desired anesthetic state, and are discharged by the conveyor belt 134a for further processing. The plates 114 of the expulsion member 112 force the birds 104 in the direction of, and onto, the conveyor belt 134a.

FIG. Ie again shows a similar arrangement as fig. 1c, this time, however, in use for releasing live, non-anesthetized poultry 104 from the container 4. Here, the conveyor belt 134 is placed in front of the compartment 121, or over some distance, e.g. 4 or 1/3 or 1/2 or 3/4 or 1/1 part of the depth of the compartment 121, introduced into the compartment 121, and the free ends of the plates 114 of the expulsion member 112 to 25 close to the roll 136 of the belt conveyor 132, or further above the conveyor belt 134. As a result, the birds 104 present in the compartment will be forced to move onto the conveyor belt 134, being transported from the compartment 121 in the direction of the arrow 126. . When the conveyor belt 134 is again brought out of the compartment 121, the expulsion member 112 follows the conveyor belt 134 at least such that the plates 114 are always directly behind, or partially above, the conveyor belt, in order to give the birds 104 no opportunity in the compartment 121 to stay behind. Subsequently, the remaining compartments of the container 4 are emptied in the same manner.

18

To prevent the birds 104 from leaving the conveyor belt 134, a cover 139 of a transparent and / or perforated material can be placed over it, so that the birds 104 can be observed on the conveyor belt 134, and as it were through a tunnel are being fed. The conveyor belt can optionally be of the perforated type 134a (see Fig. Id), wherein a stunning gas or gas mixture is brought above the conveyor belt.

In this case, the cap 139 will be substantially closed to minimize gas loss, and supply and discharge openings for the tunnel formed by the cap 139 will be provided with per se shown, per se known, passable partition walls, such as strip curtains.

FIG. 1f again shows a similar arrangement to FIG. 1c, but with no expulsion means, and the belt conveyor 132 is adapted to bring the conveyor belt 134 into the compartment 121 over the entire depth of the compartment 121. Thus, without the cooperation with expulsion means, the conveyor belt 134 can take all birds 104 present in a compartment outside the container 4 and remove them for further processing.

The arrangement according to Fig. 1g is a discharge station 150, which is in fact a variant of the discharge station according to Figs. 1b or 1c. A difference lies in the fact that the birds 104 in all compartments of a container 4 are discharged substantially simultaneously by using an expulsion member 152 with a number of horizontal series of plates 114 on an enlarged carrier 154, one series of plates 114 per compartment, combined with a series of belt conveyors 156a-156f, one belt conveyor per compartment. In this arrangement, it is no longer necessary for the roller conveyor 102 or other components of the unloading station 150 to be displaceable in the vertical direction, as was necessary in the arrangements according to Figs. 1b-1f. With a sufficient length of the plates 114, the conveyor belts of the belt conveyors 156a-156f need not extend over the entire depth into the compartments, while with a length of the plates 114 in the compartments that is smaller than the compartment depth, belt conveyors of 35 the type shown in FIG. Even belt conveyors of the type shown in Fig. If can be used, whereby the expulsion member 152 can be omitted.

FIG. 1h shows a transport unit 160 comprising a series of belt conveyors 162a-162f and a series of belt conveyors 164a-164f. The belt conveyors 164a-164f are arranged in a frame 166, which can be moved relative to a frame 168 of the belt conveyors 162a-162f in the directions of double arrow 170 with the aid of guide wheels 172 with the aid of a control gear (not shown). The belt conveyors 164a-10 164f are each of the type shown in Figs. 1b-1f, and have conveyor belts 174a-174f which are driven by motors 176a-176f for transporting birds 104 from the compartments of container 4. The control can thereby of the motors 176a-176f are such that the birds 104 are only transported to the end of the belt conveyors 164a-164f facing the belt conveyors 162a-162f, whereafter the drive of the conveyor belts 174a-174f stops. Only after the belt conveyors 162a-162f and 164a-164f are spaced sufficiently shortly apart is the drive of the conveyor belts 174a-174f started again, whereafter the birds 104 land on the belt conveyors 162a-162f, and are thereby discharged for further processing.

It is therefore possible to use the arrangement according to Fig. 1h for temporarily buffering poultry 104 on one or more of the belt conveyors 174a-174f, as Fig. 1 further illustrates. Of course, this method of buffering with two separate belt conveyors placed in series can also be used in the arrangements of Figs. 1b-1f for a single compartment 121 of a container 4.

FIG. IJ shows an unloading station 180 that substantially corresponds to the unloading station shown in FIG. 1I, with the exception of the addition of a belt conveyor 182, one end of which is mounted on a column 184, and which can be driven for a displacement of conveyor 183 in the direction of arrow 185. The bearing can be moved along the column 184 in the directions of double arrow 186 with the aid of a controllable motor 188. Thus, it is possible that the belt conveyor 182 successively at the level of each of the conveyor belts 174a-174f, after which the respective conveyor belt 174a-174f can be set into motion briefly for transferring the birds 104 located thereon to the conveyor belt 183, for discharging and further processing of the birds 104.

Although most of the unloading stations described above are primarily intended for releasing anesthetized or dead poultry, it will be clear that they can also be used for releasing non-anesthetized poultry, as in particular with reference to FIG. Ie is illustrated.

FIG. 2-6 show an arrangement with a conveyor 2 for transporting containers 4 with poultry in the direction of the arrow 3. A lockable chamber 40 comprises a turntable 41 for rotating a container located in the chamber 40 in a desired orientation . Optionally, an anesthetic gas or gas mixture can be supplied to the chamber 40 in a manner not further shown for introducing or triggering the first state of anesthesia with the poultry present in the chamber 40.

A chamber 42, which is separated from the chamber 40 by means of a movable wall, an air curtain, a strip curtain or the like, comprises a tilting mechanism 44 for tilting a container 4 located in the chamber 42 to such a position, that the poultry present in the container 4 leaves the container 4 via openings in its side wall due to the action of gravity. A belt conveyor 46 then transports the poultry to a subsequent chamber 48 provided with a belt conveyor 52 moving in the direction of arrow 50. The chamber 48 covers two functional sections: a first section 48a extending between the "A" and " B "designated sites, and a second portion 48b extending between the" B "and" C "designated sites. The chamber 42 is provided with a discharge conduit 54 for gas contained in the chamber 42. The first portion 48a of the chamber 48 is provided with a supply line 56 for supplying gas to the first chamber portion 48a and the chamber 42, as shown in FIG.

4 in particular. The second part 48b of the chamber 48 is provided with a supply conduit 58 and a discharge conduit 60 for the supply resp. discharge of a narcotic gas or gas mixture to the second chamber portion 48b, wherein the supply line 58 and the discharge line 60 are mutually coupled with the interposition of a pump / injector 62 for injecting the narcotic gas or gas mixture for maintaining the required gas concentration (s) in the second chamber portion 48b. The second chamber portion 48b is intended to cause the second anesthetic state of the poultry, which is deeper than the first anesthetic state. It is to be noted that the gas supply to and gas discharge from the chamber 42 and the chamber portion 48a can also be omitted if the anesthetic condition achieved in the chamber 40 is already sufficient.

The second chamber portion 48b is provided in its side walls with windows 63 for observing the poultry present in the chamber 48.

It is to be noted here that, alternatively, in all chambers 40, 42 and 48, such an anesthetic gas or gas mixture can be introduced that the first anesthetic condition of the poultry is reached and maintained therein. The same gas or gas mixture can be introduced into each chamber 40, 42 and 48, but different gases or gas mixtures can also be used. In the case where the same gas is used in all chambers 40, 42 and 48, separations between the chambers may be missing, or may be present for a good control of the gas atmosphere along the entire path in the chambers to be traveled by the poultry, and to facilitate maintenance, repair and cleaning of the rooms.

Upon leaving the chamber 48, the poultry lands on a belt conveyor 64, where it is positioned by persons 66 and hung on hooks 68 of an overhead conveyor 70 to be transported to a bleeding station (not shown).

The arrangement further comprises an optional chamber 72 which is separated from the chamber 42 by means of a movable wall, an air curtain, a strip curtain or the like, and in which the container 4 discharged into the chamber 42 can be rotated on a rotating platform 74. A cleaning device 76 for cleaning containers 4 is connected to the chamber 72.

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22

FIG. 7 shows a similar arrangement to that of FIG.

2, but the chamber 48 and the belt conveyor 64 are missing.

Poultry supplied in containers 4 is brought into the first anesthetic state in the chamber 40 and / or the chamber 42. To this end, the supply line 52 is connected to the chamber 42. The containers 4 are unloaded into the chamber 42, and the unloaded poultry and brought into the first anesthetic state are supplied to a suspension station 80 where the poultry is hooked by hangers 82 with the legs 84 on hooks 84 is suspended from an overhead conveyor 88 moving in the direction of arrow 86. The suspension station 80 may be provided with a conveyor, not further shown, such as a belt conveyor, for moving the poultry in the same direction as the overhead conveyor, after it has been supplied from the chamber 42, and prior to its suspension on the hooks 84.

15

Claims (51)

A method for processing slaughtered animals, in particular birds, in a slaughterhouse, comprising the steps of: (a) supplying the slaughtered animals in containers, wherein each container comprises several compartments; (b) unloading the slaughtered animals from one of the containers at a discharge station; (c) coupling a released slaughter animal to a transporter; and (d) slaughter of the slaughtered animals, characterized in that several unloading stations are provided along the path of the conveyor, wherein in step (b) slaughter animals are unloaded simultaneously from a plurality of containers located in different unloading stations. 15 Method according to claim 1, wherein each container is passed along different unloading stations, and in each unloading station one or more subsequent compartments of said container are unloaded. Method according to one of the preceding claims, wherein in step (b) animals for slaughter are simultaneously unloaded from several compartments of one of the containers. 4. Method as claimed in claim 3, wherein in step (b) at the same time slaughter animals are released from all compartments of one of the containers. 5. Method as claimed in any of the foregoing claims, wherein the slaughtered animals are buffered after step (b) and before step (c). A method according to any one of the preceding claims, wherein step (c) comprises positioning the slaughter animals. A method according to any one of the preceding claims, comprising the step of: 1 i.i. WH - anesthetize the animals for slaughter contained in the containers. 8. Method as claimed in claim 7, wherein the animals for slaughter are brought into a first anesthetic state during anesthesia in which they are unconscious, and the oxygen supply to the muscles of the animals for slaughter remains substantially intact. The method of claim 7 or 8, wherein the first anesthetic condition is maintained at least during step (b). 10 The method of claim 9, wherein the first anesthetic condition is maintained until step (d). A method according to any of claims 7-9, comprising after step 15 (b) and before step (d) the step: - anesthetizing the slaughtered animals, wherein the slaughtered animals are brought into a second state of anesthesia deeper than the first state of anesthesia. A method according to claim 11, wherein the slaughter animals when being brought into the second state of anesthesia are substantially stunned sequentially. 13. Method as claimed in claim 11 or 12, wherein the slaughtered animals are killed when they are brought into the second state of anesthesia. The method of any one of claims 7-13, wherein the first state of anesthesia is triggered by a gas anesthetic. 30 The method of any one of claims 11-14, wherein the second state of anesthesia is triggered by a gas anesthetic. A method according to claim 14 or 15, wherein the stunning takes place in one or more chambers. A method according to any of claims 14-16, wherein the gas anesthesia of the slaughter animal is triggered by anoxia. A method according to claim 17, wherein the slaughtered animal is brought into an atmosphere with at most 2 vol.% Oxygen. 19. Method as claimed in claim 18, wherein the slaughtered animal is brought into an atmosphere with at most 10% by volume of air, the remaining part of the atmosphere consisting of one or more of argon, nitrogen and carbon dioxide gases. 20. Method as claimed in any of the claims 14-16, wherein the gas stunning of the slaughtered animal is triggered by hypercapnic hypoxia. A method according to any of claims 14-16, wherein the gas anesthetic of the slaughtered animal is triggered by hypercapnic hyperoxygenation. 20 A method according to any of claims 14-16, wherein the gas anesthetic of the slaughtered animal is induced in an induction phase by a gas mixture of 30 volume% oxygen, 40 volume% carbon dioxide and 30 volume% nitrogen, and in a final phase is produced by a gas mixture of 80 vol.% carbon dioxide with 5-15 vol.% oxygen. A method according to any one of claims 14-16, wherein the gas anesthetic of the slaughtered animal is effected by the steps of: bringing the slaughtered animal for approximately 20 seconds into a first gas atmosphere comprising approximately 20% by volume of carbon dioxide and approximately 20 vol% oxygen; placing the slaughtered animal for approximately 50 seconds in a second gas atmosphere comprising approximately 40 vol.% carbon dioxide and approximately 20 vol.% oxygen; and bringing the slaughtered animal for about 30 seconds into a third gas atmosphere comprising about 50 volume% carbon dioxide and about 20 volume% oxygen. The method of any one of claims 7-13, wherein the first state of anesthesia is triggered by an electrical anesthetic. 25. Method as claimed in any of the claims 11-13 or 24, wherein the second state of anesthesia is brought about by an electrical anesthetic. 26. Method as claimed in claim 24 or 25, wherein the electrical anesthetic of the slaughtered animal is produced with an alternating current with a frequency of at least 20 Hz and at most 2.5 kHz, in particular with a frequency of 75-125 Hz . The method according to claim 26, wherein the frequency is 200-2000 Hz, in particular 450-550 Hz. 20 A method according to any of claims 7-13, wherein the first state of anesthesia is brought about by exposing each slaughter animal or a part thereof to high-frequency radiation, in particular high-frequency electromagnetic radiation. 25 A method according to any of claims 11-13 or 28, wherein the second state of anesthesia is brought about by exposing each slaughtered animal or a part thereof to high-frequency radiation, in particular high-frequency electromagnetic radiation. 30 The method of claim 28 or 31, wherein a frequency of 900-1000 MHz is used. A method according to claim 28 or 29, wherein a frequency of 2400-2500 MHz, in particular 2450 MHz, is used. Luck: - - / A method according to any one of the preceding claims, wherein the container is the transport unit with which the slaughtered animals are transported to the slaughterhouse. The method of any one of the preceding claims, wherein the slaughter animals are turkeys. 34. Device for processing slaughtered animals, in particular birds, in a slaughterhouse, wherein the slaughtered animals are supplied in containers, and each container comprises several compartments, which device comprises: an unloading device for unloading the slaughtered animals from the containers; transport means for transporting the containers 15 along the unloading device; a slaughtering device disposed downstream of the unloading device; and a conveyor for coupling the unloaded slaughtered animals and transporting the slaughtered animals from the unloading device to the slaughtering device, characterized in that the unloading device comprises a number of unloading stations which are placed along the path of the conveyor and which are each arranged to at least partially unload one of the containers, and wherein the unloading device is adapted to unload slaughter animals simultaneously from a plurality of containers located at different unloading stations. 35. Device as claimed in claim 34, wherein the unloading device comprises a number of unloading stations, each of which is adapted to unload one or more following compartments of one of the containers transported along the unloading stations by the transport means. An apparatus according to claim 34 or 35, wherein the unloading device is adapted to unload animals for slaughter from a plurality of compartments of one of the containers at the same time. An apparatus according to claim 36, wherein the unloading device is adapted to unload animals for slaughter from all compartments of one of the containers at the same time. An apparatus according to any of claims 34-37, wherein the unloading device comprises a buffer device. The device of claim 38, wherein the buffer device comprises a controlled conveyor. 10 Device as claimed in any of the claims 34-39, wherein the unloading device comprises tilting means for tilting containers. Device as claimed in any of the claims 34-39, wherein the releasing device comprises expulsion means for moving the slaughtered animals to an open side of the container. 42. Device as claimed in claim 41, wherein the container comprises a wall formed by bars, and wherein the expulsion means can be moved from the outside of the container between the bars into the container. 43. Device as claimed in claim 42, wherein the expulsion means comprise a series of expulsion elements which, at an end to be introduced into the container, extend over a part of the height of the container or a compartment thereof. Device as claimed in claim 43, wherein the expulsion elements are substantially T-shaped. 30 The device of claim 43, wherein the expulsion elements are plate-shaped. Device as claimed in any of the claims 41-45, wherein the container comprises several compartments, and wherein the expulsion means 3 parts per compartment are active. 47. Device as claimed in any of the claims 34-46, wherein the unloading device comprises at least a substantially horizontal first belt conveyor with an endless conveyor belt, of which first belt conveyor at least a part is intended to be introduced into the container near a bottom thereof or near a bottom of a compartment of the container. Device as claimed in claim 47, wherein the conveyor belt 10 is driven such that it is displaced over a predetermined distance when introducing said part of the first belt conveyor into the container. 49. Device as claimed in claim 47 or 48, wherein a subsequent belt conveyor is connected to the discharge end of the first belt conveyor for buffering the slaughtered animals discharged from the container with the first belt conveyor. An apparatus according to any of claims 34-49, further comprising an anesthetic device for anesthetizing the slaughtered animals in containers, with transport means for transporting the containers through the anesthetic device, the anesthetic device being upstream of the unloading device and wherein the animals for slaughter are brought into the stunning apparatus in a first state of anesthesia in which they are unconscious, and the oxygen supply to the muscles of the animals for slaughter remains substantially intact. An apparatus according to claim 50, wherein the anesthetic device 30 comprises at least one anesthetic space, and wherein the releasing device is arranged in the at least one anesthetic space. Device as claimed in claim 50 or 51, further comprising a second anesthetic device arranged downstream of the releasing device for anesthetizing the released slaughter animals, with second transport means for transporting the slaughter animals, wherein the slaughter animals are in a second state of anesthesia deeper than the first state of anesthesia. 53. Device as claimed in claim 52, wherein the second transport means are adapted to transport the respective slaughtered animals substantially sequentially.