SU935037A1 - Apparatus for ventilation of hutch battery - Google Patents

Description

(54) DEVICE FOR VENTILATION OF CELL BATTERIES

one

The invention relates to devices for providing an optimal microclimate in poultry and other livestock buildings and can be used for keeping both birds and other small domestic animals in cage batteries.

A device for ventilating cellular batteries is known, including exhaust ventilation channels separated from cells by perforated partitions for exhausting air, supply and heat exchange channels, exhaust and supply ventilation 1.

The drawbacks of the known device are that its heat exchangers do not use the biological heat of birds, in particular the heat released by the droppings. In addition, when the exhaust air is cooled, the condensate forms in the heat exchange channels, and in severe frosts their surface is covered with a layer of frost, the heat transfer through the field drops sharply and the heat exchangers become inoperative just when their role is especially important.

The aim of the invention is to increase the efficiency of the use of biological.

heat in the cell battery ventilation device.

This goal is achieved by the fact that perforated partitions have holes for dropping manure into the exhaust ventilation channel, blocked by butterfly valves, and the heat exchange channels are located in the exhaust ventilation channel and are made in the form of two groups of tubular heat exchangers, which are combined with manifolds and equipped with automatic shutters for alternately opening them, with trays and a scraper for removing litter at the bottom of the exhaust ventilation channel, and exhaust and intake ventilation tori installed

15 from the discharge side of the manure from the exhaust vent.

At the same time, perforated partitions

with holes for dropping manure made of anti-corrosion polymer

material, and butterfly valves are made from anti-adhesive material.

FIG. 1 - the proposed device plan; in fig. 2 is the same; the cross-section A-A in FIG. one.

A device for ventilating cellular batteries includes a vent air duct 1 separated from cells 2 by a perforated partition 3 with air exhaust holes 4, heat exchange ducts 5 located in the air vent channel 1, inlet channels 6, air holes 7 for dropping manure in perforated partitions 3, covered with butterfly valves 8, corner scraper 9 for dropping manure with protrusions 10 acting on butterfly valves 8 for opening them, scraper 11 for removing manure at the bottom of the exhaust vent of the cooling channel 1, the exhaust duct 12 is connected to the exhaust fan 13, and the supply fan 14 is connected through distribution manifolds 15 and 16 with automatic dampers 17 and 18 to the heat exchange channels 5; The intake ducts 6 are connected to two groups of heat exchange ducts 5 via collecting headers 19 and 20, a collecting channel 21 and a diversion channel 22 with a damper 23 for supplying air during the warm period of the year.

A device for ventilating cellular batteries operates as follows.

Air from the cells 2 is polluted by gases and water vapor through the holes 4 in the perforated partitions 3, through the exhaust ventilation channel 1, the exhaust duct 12 to the outside with the help of the exhaust fan 13. During the working movement of the corner scraper 9, the latter acts the protrusion 10 on the butterfly valves 8, which overlap, the openings 7 for dropping the manure. The butterfly valves 8 open and the droppings are dumped into the exhaust ventilation duct 1, and additional air leakage through the droppings hole 7 reduces the penetration of harmful gases and vapors into the cages 2 and the room and, in addition, helps the vanes to stick to cleaning. During the cold period of the year, the coolant supply air is supplied through the heat exchange channels 5, which, when passing through the exhaust ventilation duct 1 filled with warm exhaust air, is heated. The presence in the exhaust ventilation duct 1 of the litter and its vapor leads to an increase in the efficiency of the use of biological heat. The supply air heated in the heat exchange channels 5 is then supplied to the room by means of the supply channels 6, and the manure from the exhaust ventilation channel 1 is removed periodically with the help of scraper II. In the cold period of the year, the outside cold air is supplied by the supply fan 14 through manifolds 15 and 16 with flaps 17 and 18 through heat exchangers 5, made in the form of two tubular heat exchangers, prefabricated manifolds

W and 20 and through the inlet channels 6 into the room. Due to the presence of warm exhaust air in the exhaust ventilation channel 1, as well as water vapor and gases from the litter, the efficiency of utilization of biological heat is increased. Yes, the manure itself has a temperature higher than the air temperature of the room and therefore also transfers heat to cold air. In severe frosts, when the ambient temperature is below minus 18-20 ° C, frost forms in the form of a snow splinter on the surface of the heat exchange channels 5, as moisture from the air and manure condenses and freezes on the cold surfaces of the heat exchanger. At the same time, the efficiency of heat transfer sharply decreases. In order to increase the utilization of biological heat in severe frosts, automatic shutters 17 and 18 are turned on. One of the shutters, for example, 18, is closed for the time required to defrost the first group of tubular heat exchangers of the heat exchange channel 5, and then reopens. After a certain time, the other flap 17 closes and, after thawing, the other.

A group of tubular heat exchangers also opens. Due to the alternate closing of one or the other, even in severe frosts, the tubular heat exchangers deflect off frost, thereby greatly increasing the efficiency of the heat exchangers. During the warm period of the year, the heat exchange channel 5 is shut off by closing the dampers 17 and 18, and the intake air is supplied to the intake channel 6 through the bypass channel 22 with the damper 23. Since the exhaust fan 13, the inlet fan 14 and the collecting channel 21 are located with one end of the cell batteries, in the cold period of the year the intake cold air moves in the tubes of the heat exchange channel 5 in the opposite direction

the movement of warm exhaust air and litter, i.e. counterflow of heat carriers is carried out, which also increases the efficiency of utilization of biological heat.

To increase work efficiency

The devices are perforated partitions 3 and butterfly valves 8 are made of anti-corrosion and anti-adhesive material, which prevents sticking of litter on their surface and contributes to their longer working life.

Claims (1)

1. A device for ventilating cellular batteries, including exhaust ventilation channels separated from cells by perforated partitions for exhausting air, inlet and heat exchange channels, exhaust and inlet fans, characterized in that