NL8701690A - Cattle multi-feed silo system - has transporters with helical screw drives, to supply partitioned feed troughs - Google Patents

Abstract

A silo feed system supplies a mixture of fodder and/or medicine to partitioned feed troughs. Helical feed screws, at the silo bottom, transport the fodder to a common feed tube. The multi feed system (1) includes three silos (5,6,7), with a silo outlet (8) ending at a helical feed screw (9) driven by motor (30) and rotatably supported in a box (10). A feed screw outlet (11) is closeable with a valve (12) activated by a piston cylinder unit (13). An outlet (11) is connected to a feed tube (14) with disc type cams (16) and a cable (17) driven by a gear box (18) and passing helical screw drive outlets (11,48,49). Fodder and/or medicine mixture is then supplied to troughs (2) of partitions (3).

Description

# w-. * P HP / AB / H-1 - 1 - belongs to NL 87.01690 ll

Multi-feeding system and a feeding unit

The invention relates on the one hand to a multi-feeding system, and on the other hand to a feeding unit for a mono or multi-feeding system according to the invention.

In livestock farming, for example, the manure problem has returned to phased feeding due to new knowledge and experience. The livestock is no longer moved, but now each individual cage is fed via a single feed tube, different kinds of feed and possibly feed with medicines.

The known multi-feed system comprises a number of silos which are supplied with new feed and residual feed via long high jacks and which each connect via a silo outlet to a common feed tube, which silo outlets are each closable with expensive, susceptible pneumatic slides.

The object of the invention is to provide a multi-feed system, wherein the long high jacks and possibly the expensive, malfunction-prone pneumatic slides can be dispensed with. This is achieved in that the multi-feed system 20 according to the invention comprises a number of silos each intended for a type of feed or medicines and the like, of which a silo outlet opens onto a jack which connects via a jack outlet to a system that transports the feed to the lofts and back to the silos via a common feed tube, with a residual bunker with a bunker outlet opening on the auger of the respective silo, and communicating with the feed transport system via a bunker inlet that can be closed with a valve, and means for controlling the multi-feed system.

30 By using the residual bunker connected to the feed system, which on the other hand flows into the common auger, the long, high augers can be dispensed with, while in principle the expensive, fault-prone pneumatic sliders can be used .8801690 11 - 2 - r 4 missing because the stationary auger prevents feed transport along it.

In a special embodiment, a silo wall can form part of the residual bunker. A space-saving, compressed version arises if the residual bunker is a residual compartment present in the silo separated by a silo wall.

if the residual bunker flows upstream of the respective silo into the common auger, only 10 feed will be extracted from the silo with a rotating auger, if the residual bunker is completely empty. This means that when feed is exclusively fed to the silos, the dosed feed has essentially the same freshness and no accumulation of residual feed can occur.

According to another embodiment, the residual bunker opens downstream of the respective silo onto the common auger. In order to ensure in this embodiment that the feed is as short as possible in the residual bunker, it is hereby preferred that the pitch of a mortar from the residual bunker outlet increases. The transport capacity of the auger thus increases from the residual bunker, whereby feed is extracted from the residual bunker simultaneously and possibly accelerated with respect to the silo.

Finally, the invention also relates to a feeding unit for a mono- or multi-feeding system, which feeding unit according to the invention comprises a silo, from which a silo outlet opens to a auger which can be connected via a auger outlet to a feed transport system, and a residual bunker that opens onto the auger with a bunker outlet and that can be connected to the feed transport system via a bunker inlet.

It will be clear that a mono-feeding system comprises only one feeding unit according to the invention, while a multi-feeding system comprises a number of series-connected feeding units.

Mentioned and other features of the feeding unit and the multi-feeding system according to the invention will be elucidated hereinafter by means of a number of non-limitative exemplary embodiments, with reference to the accompanying drawing.

5 In the drawing:

Fig. 1 and 5 each show a schematic top view of a multi and mono transport system according to the invention;

Fig. 2 is a larger-scale section along line 10 II-II of FIG. 1;

Fig. 3 and 4 each show a different variant of the cross-section of Fig. 2; and

Fig. 6 is a larger-scale section along the line VI-VI from fig. 5.

FIG. 1 shows a multi-feed system 1 according to the invention for providing the feed transport to pens 3 provided with feed troughs 2, separated in pairs by corridors 4.

The multi-feed system 1 comprises three silos 5-7, each of which is intended for a different type of feed or medicated feed. The silo 5-7 is provided with a silo outlet 8 which opens onto a auger 9 which is driven rotatably with a motor 30 in a auger box 10. A auger outlet 11 can be closed with a valve 12 which is operated with a piston cylinder system 13 is operable.

The auger outlet 11 communicates with a feed tube 14 of the known feed transport system 15. This feed transport system 15 comprises the feed tube 14 in which a cable 17 provided with disc-shaped carriers 16 is guided.

The cable 17 is driven in a drive box 18 and successively passes the auger outlets 11, 48 and 49 and 11 of the silos 7, 6 and 5, the feed troughs 2 of the pens 3 and finally bunker inlets 19-21 of the residual bunkers 22- 24 of silos 5-7, respectively.

As shown in Fig. 2, a silo wall 25 forms a part of the residual bunker that opens upstream from the silo outlet 8 with its outlet 26 to the auger 9 shared with the silo 7.

The bunker inlet 21 can be closed with a valve 28 operable with a piston cylinder system 27.

With control means not shown, the valves 5, 12 and 28 of the silos 5-7 are adjustable in a position corresponding to desired feed to be dosed.

The operation of the multi-feeding system 1 according to the invention is as follows. If feed has to be supplied from the silo 7 to the feed troughs 2, the cable 17 and the motor 30 of the auger 9 are energized from the drive box 10. The valve 12 and possibly the valve 28 are opened, the corresponding valves for the silos 5 and 6 are closed. First of all, feed present in the residual bunker 24 is transported under the outlet of the silo 7 and after the residual bunker 24 has been emptied, feed is discharged into the auger 9 via the silo outlet 8. The feed is propelled by means of the cable 17 through the cleats 16 transported to the feed troughs 2. Excess feed returns to the residual bunker 24 via the bunker inlet 21.

After the desired amount of feed has been dosed, the valve 12 is closed and the cable 17 is pulled around until all the feed present in the feed tube 14 is discharged into the residual bunker 24.

After the valve 28 has been closed, it is possible to supply feed from the other silos to the feed troughs 2.

Fig. 3 shows a variant for the feeding unit 34 of fig. 2, wherein the residual bunker is integrated in the silo 7. An angled bunker wall 31 separates a residual compartment 29 at the bottom of the silo 7, so that no feed up to 30 from the silo 7 in the residual compartment 29 can get. It should be noted that the auger outlet 11 cannot be closed with a valve in this case. Nevertheless, the basic advantages of the invention are achieved. Otherwise, the function of the feeding unit 35 is the same as that of Fig. 2.

FIG. 4 shows a variant of the feeding unit 34 of fig. 2 and the feeding unit 35 of fig. 3. This feeding unit 32 comprises a silo 33 which, with a silo outlet 36, opens onto a auger 37 which driven with the motor 30, it is rotatably mounted in the auger box 38. Upstream of the silo 33, on the auger 37, a residual bunker 40 opens with its bunker outlet 39.

In accordance with Figs. 2 and 3, the auger outlet 41 and the bunker inlet 42 are connected to the common feed transport system 15. The pitch of the auger is increased from the bunker outlet 39, so that more feed can be transported from the bunker outlet 39 per auger revolution, so that when the motor 30 is energized with the aid of the auger 37, feed can be simultaneously extracted from the silo 33 and from the residual bunker 40. Preferably, the pitch is increased such that during one feeding cycle the entire contents of the residual bunker 40 are extracted.

FIG. 5 shows a mono feed system 43 with one feeding unit 44 according to the invention shown in section in FIG. 6.

The feeding unit 44 comprises a silo 45 which opens onto the auger 9 with the silo outlet 8, while upstream of the silo 45 a residual bunker 46 opens with the bunker outlet 26 onto the common auger 9. It is noted that the bunker inlet 47 cannot be closed with a valve 28.

Nevertheless, a number of advantages of the invention are achieved.

Finally, it is noted that it is possible in principle to split the common auger 9 into a waste bunker auger and a silo auger which are connected either in parallel or in series to the feed transport system 15.

30 .8801690

Claims (13)

Multi-feed system, comprising a number of silos each intended for a type of feed or feed provided with medicines and the like, of which a silo outlet opens into a jack which connects via a jack outlet to a system 5 that transports the feed to the pens to and from the silos via a common feed tube, wherein a residual bunker with a bunker outlet opens to the auger of the respective silo, and is connected via a bunker inlet with a valve to the feed transport system, and means for controlling of the multi-feed system. Feeding system according to claim 1, characterized in that a silo wall forms part of the residual bunker. 3. Feed system according to claim 2, characterized in that the residual bunker is a residual compartment present in the silo separated by a silo wall. Feeding system according to claims 1-3, characterized in that the residual bunker opens upstream of the respective silo on the common auger. Feeding system according to claims 1-3, characterized in that the residual bunker opens downstream of the respective silo onto the common auger. Feeding system according to claim 5, characterized by a screw whose pitch increases from the residual bunker outlet. 7. Feeding unit, for a mono or multi-feed system, comprising a silo, of which a silo outlet opens onto a auger which is connectable via a auger outlet to a feed transport system, and a residual bunker opening out onto the auger with a bunker outlet and which can be connected to the feed transport system via a bunker inlet. Feeding unit according to claim 7, characterized in that the bunker inlet can be closed with a valve. -8801690 - 7 - J ί * Feeding unit according to claim 7 or 8, characterized in that a silo wall forms part of the residual bunker. Feeding unit according to Claim 9, characterized in that the residual bunker is a residual compartment separated in the silo by a silo wall. Feeding unit according to claims 7-10, characterized in that the residual bunker opens upstream of the respective silo on the common auger. Feeding unit according to claims 7-9, characterized in that the residual bunker opens downstream of the respective silo onto the common auger. Feeding unit according to claim 12, characterized by a screw whose pitch increases from the residual bunker outlet. 15 * 88 0 16 9 0