NL8403082A - Ventilation exhaust shaft for pigsty - has upper cap or lower valve-piston device to control intensity of fan-generated airflow through shaft - Google Patents

Abstract

The ventilation shaft has an airflow-varying device at its lower end. The device (26) is provided with a valve or piston which is positionable by an electric servo motor (13) to selectively block or uncover openings in the shaft wall. The livestock house contains a fan (4) to generate the airflow in the shaft. In plan view, the wall openings are V-like. Alternatively, the device can be located at the top of the shaft, being in the form of an adjustable cap (5). The cap has its concave side facing the shaft, and is supported by a vertical rod slidingly located in a bushing within the shaft upper part.

Description

f: * N238

Adrianus Henrikus Josephus Smulders Bladel 5 Extraction ventilation duct for a cattle shed.

The invention relates to an extraction ventilation duct for a livestock shed, in particular a pigsty, to a stable provided with such an extraction ventilation duct and to a climate control system for a livestock house provided with such an extraction ventilation duct. The invention also relates to the constituent parts apparently intended for use in such a ventilation tube.

In modern livestock farming, where a large number of livestock, for example cows, pigs or poultry are present in a building, it is of great importance to carefully control the climate in these buildings, which will be called livestock sheds here. One of the most important factors in this respect is the maintenance of a certain, very uniform temperature.

In such livestock houses for pigs it is usual to build practically completely closed rooms in which the pigs are housed. For the air conditioning it is necessary to maintain a very regular but variable air flow in the room. This is usually done by means of an exhaust fan located on one side at the top of the room.

The air supply usually takes place at the top side of the wall opposite the exhaust ventilation duct.

The temperature in the room is largely determined by the heat output of the pigs. This heat output varies greatly according to the number of pigs in the room and the live weight of the pigs.

In pig fattening, the pigs are brought into the room at a young age when they are still light in weight. During the stay in the room they are fertilized until they have reached the required final weight. It is clear 8403082 sr λ -2- that the heat development of the young pigs is considerably smaller than the heat development of the fattened pigs. As a result, the heat development varies considerably during the fertilization period. Naturally, the temperature also strongly depends on the state of the supplied air, in particular the temperature and the humidity thereof. This state will be very different, especially in summer and winter, and will also be influenced by wind currents. Since it is desirable to keep the climate in the house of the house as uniform as possible during the entire manure period, it is necessary to be able to properly regulate the air flow through the room. By way of illustration, the table below lists the number of m3 per hour that is necessary under the different conditions, for a given case.

Weather conditions kg / Pigs total% m3 / hour present pigs live weight 20 ---------------------------------- --------------------------- winter 80 x 25 = 2000 20 * 400 summer 80 „x 25 - 2000 100 = 2000 winter 80 x 100 = 8000 20 = 1600 summer 80 x 100 = 8000 100 = 8000 25

The table shows that for this example a variation in the airflow is necessary from 400 m3 per hour to 8000 m3 per hour. This variation in the amount of air required will, of course, be different for other examples, but it always remains valid that the maximum amount of air is very high compared to the minimum amount of air required.

Varying the airflow between the minimum and maximum values is generally accomplished by varying the speed of an axial fan mounted in the exhaust ventilation duct. Although a fairly wide control range can be realized in this way by regulating the supply voltage supplied to the fan, it has been found in practice that this control leaves something to be desired, especially at lower amounts of necessary air. Precisely at these low amounts of air, when the fan operates at low voltage and rotates slowly, the amount of air flowing through the chamber is strongly dependent on all kinds of factors, in particular the pressure difference between the chamber and the outside air. This pressure difference is strongly influenced, for example, by a sudden, even short-term rise in temperature in the room or outside and by changes in the wind's strength and or direction. With low amounts of air required, the climate in the room 15 of the shed will therefore not be particularly constant, which is very detrimental to the condition of the pigs and in particular has a bad influence on their growth. At higher fan speeds, these influences are considerably smaller.

In order to somewhat compensate for the problem described above, on the underside of the extraction ventilation ducts which are always arranged vertically on the livestock shed, members, usually called diaphragms, have been provided with which the supply opening to the ventilation duct is enlarged or reduced as desired can become. These diaphragms usually consist of two plates with V-shaped notches that can be moved towards or away from each other. These plates slide over each other and the surface between the V-shaped incisions naturally determines the through-flow opening. In some cases, a so-called iris diaphragm with blades has also been used.

The speed of the fan in the extraction duct is sometimes controlled manually, based on 35 experimentally obtained data, but also via an 8403082 * 'Η * - -4- micro-processor that receives a control signal from a temperature sensor in the livestock room · Adjusting the opening in the diaphragm, together with controlling the fan speed, provides a significant improvement in controlling the desired airflow, especially when only small amounts of air are required to be.

The setting of the aperture has so far always been done by hand. This is, of course, a time-consuming activity, not only because of the adjustment of the diaphragms themselves, but also because of the regular check necessary to determine the desired airflow according to the temperature in the room. The farmer, or fattener, must therefore always reset the diaphragm under changing weather conditions, even with an automatically controlled fan.

The main object of the present invention is to improve upon this and to obtain further advantages, which will be explained hereinafter.

Above the exhaust ventilation duct there is always a cover, in particular intended against rain impact and for guiding the exiting air flow. The shape of this cover, which is usually and also referred to as "cap" in the following description, naturally has an influence on the resistance encountered by the outflowing air. This also influences the back pressure at the fan. Since the cap always has a fixed position in the installations hitherto known, nothing can be changed about a change in the back pressure, for instance due to a change in the wind direction and / or wind strength. This is a drawback which can be largely avoided by means of a special embodiment of an exhaust ventilation duct according to the invention. Namely, in this particular embodiment, the cap is adjustable in height 35 above the end of the ventilation duct. This cap can then take over the function of the diaphragm on the underside of the ventilation duct. In general, however, according to a preferred embodiment of the present invention, both an adjustable diaphragm on the bottom side 5 and an adjustable cap on the top side of the exhaust ventilation duct will be used. These two organs can then be operated simultaneously or separately. Preferably they are simultaneously operated, for example, by a mechanical coupling between the actuators of the diaphragm and the actuator of the cap.

An exhaust ventilation duct according to the invention, for vertical installation on a livestock shed, in particular a pigsty, contains an adjustable axial fan and is characterized in that at least one end of the duct is provided with an element with which the strength of the air flow through the duct is can be changed because this member has an air passage opening, the size of which is adjustable by an electric servo motor.

The servo motor is preferably controlled by a micro-processor which receives control signals from one or more temperature sensors in the livestock room. This same micro processor can also control the fan speed. By a suitable choice of the settings of the microprocessor, a desired relationship can be made experimentally between the change in the speed of the fan and the settings of one or both members at the ends of the ventilation sleeve. Therefore, even with a small amount of air required, an extremely accurate adjustment thereof can be realized, especially when the position of the diaphragm and of the cap is simultaneously controlled.

According to the invention, the member on the underside of the sleeve is preferably designed in such a way that it contains a valve or piston, which runs coaxially with the sleeve 35 and can be displaced in the direction of the shaft of the sleeve and one or more recesses in the 840 30 82 -6 wall of the sleeve, the effective passage area of which is determined by the position of the valve or piston.

It is particularly expedient here that the recesses in the wall of the sleeve are formed in such a way that the air passage characteristic of the effective passage opening thereof, depending on the position of the piston or valve, corresponds to that of a correspondingly iris diaphragm guided in a wise way. This achieves a control characteristic of the entire assembly, which is also extremely accurate even in the low range of the air volume to be displaced.

According to the invention, the recesses are formed in the wall of the tube in such a way that they are substantially V-shaped in appearance, the narrow part of the V-shape having two parallel legs over a relatively short part.

In a preferred embodiment of the invention, the movable cap is in the form of a spinning top with the tip 20 facing the sleeve, with a concave surface as viewed from the sleeve. This shape ensures a particularly good outflow of the air because a certain streamline shape is realized. This special shape gives an even better control possibility and moreover the air is more or less pushed upwards in an upward direction, so that practically no contamination of surrounding parts of the stable, for instance the roof, takes place.

The movement of the cap is effected by a vertical rod attached to the cap which is mounted in a sleeve in sleeve 30, which sleeve is fixedly secured, by means of side stripping, on the inside of the sleeve wall.

The invention will now be elucidated with reference to a drawing, in which, partly in section and partly in view, the entire arrangement is given of an embodiment of a ventilation duct according to the invention * 8403082 «-7- τ2 Φ Ιη figure 1 with 1 indicates the ventilation duct which has a widened section at the bottom 2

The tube is suspended in a beam construction (not shown) and preferably consists of polyester synthetic resin 5 possibly reinforced with glass fiber · The radial fan 4 is located approximately on the separation of the cylindrical part 1 and part 2. At the top is the vertically adjustable cap 5 which is in the form of a top, the tip of which faces the fan. The vertical rod 6 carrying the cap 5 passes through nylon rings in the part 7 which is attached to the inner wall of the tube 1 by means of the transverse strips 8 which are preferably aluminum and glued to the wall of the tube 1 . The vertical rod 6 of the cap continues in a rod 9 and is attached thereto by means of a bolt 10. This bolt 10 passes through a slot either in the rod 6 or in the rod 9 and the cap can thereby be placed on the correct height · This adjustment usually only takes place ·%> * once during installation. At the bottom end, the rod 9 is connected via the rod 11, which extends through a slot 12 into the tube 1, with a rod system with which the cap is adjustable in height. This linkage is operated by the servo motor 13 which carries one eye 14 fixed to the housing of the motor 13 at one end · At the other end 25 the shaft 15 of the motor protrudes and this shaft is adjusted in length · when energizing the motor. The total length from the eye 14 to the eye in the rod 15 changes as a result. The eye 16 of the rod 15 is rotatably connected to the lever 16; at the other end, the eye 14 is rotatably connected to the lever 17 · This lever 17 rotates about an axis 18 which is held in fixed position relative to the sleeve by the support piece 19. The levers 16 and 17 are coupled by the rod 22. The lever 16 rotates about the shaft 20 which is mounted in the rod 21. Thus, the lever 16 does not revolve around a fixed point. The servo motor 8403082

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-8- is therefore suspended, as it were. When the length between the eye 1 and the eye in the rod 15 is increased or decreased, the levers 16 and 17 move apart or towards each other and thereby operate the rod 11 with the cap 5 connected thereto. This "floating" arrangement The servo motor 13 saves space because the motor 13 does not have to perform a circular movement around a fixed point.

Furthermore, a rod 23, which includes a shaft 20, is pivotally coupled to the rod 24. The rods 21 and 24 are jointly coupled to a short rod 25 (rotatable) which carries the piston or valve 26, with the size of the diaphragm 27 can be controlled. According to the invention, parallel guidance of the piston or valve 26 is achieved by the rod systems 22, 23 and 12, 24. The shape of the opening 27 is such that the characteristic of its effective passage opening, depending on the position of the piston 26, corresponds to that of an iris diaphragm. This achieves that the accuracy of the control at low air volumes is very high, which otherwise cannot be achieved.

The invention is not limited to the exemplary embodiment shown. For example, the portion of the sleeve under the fan may have a gradually increasing diameter downward instead of the abrupt increase in diameter according to the illustrated embodiment. The valve or piston may have a different shape. However, the shape shown is preferred according to the invention, because it is optimal from the point of view of strength, flow capacity and with regard to possible contamination.

8403082

Claims (12)

1. Suction ventilation duct for vertical installation on a cattle shed, in particular a pig house, which contains an adjustable axial fan, characterized in that the duct is provided at at least one of the two ends with an element with which the strength of the air flow can be modified by the sleeve because this member has an air passage opening, the size of which is adjustable by an electric servo motor. 2. Extraction ventilation duct according to claim 1, characterized in that the member on the underside of the duct contains a valve or piston which runs coaxially with the duct and can be displaced in the direction of the shaft of the duct and one or more recesses in the wall of the sleeve, the effective passage area of which is determined by the position of the valve or piston. Extraction fan according to any one of the preceding claims, characterized in that the recesses in the wall 20 of the sleeve are formed such that the air passage characteristic of its effective passage opening, depending on the position of the piston or valve, corresponds to that of a similarly controlled iris diaphragm. Extraction ventilation duct according to one of the preceding claims, characterized in that the recesses in the wall of the duct are substantially V-shaped in view, the narrow part of the V-shape having two parallel lines over a relatively short section . 5. Extraction ventilation duct according to claim 1, 2, 3 or 4, characterized in that the element at the top of the duct is a cap I adjustable in height I, situated above the duct. 6. Extraction ventilation duct according to claim 5, characterized in that the cap is in the form of a top, pointed with the tip 8403082-10-j0 *, with a concave surface seen from the duct. 7. Extraction ventilation duct according to claim 5 or 6, characterized in that the cap is carried by a vertical rod slidably mounted in a guide fixed in the upper part of the ventilation duct. 8. Extraction ventilation duct according to one or more of the claims 1, 2, 3, 4, 5, 6 or 7, characterized in that the members at the two ends of the duct are mechanically coupled to each other such that when enlarging or decreasing the passage opening of one of the members is also enlarged or reduced the passage opening of the other member. 9. Extraction ventilation duct according to one or more of the preceding claims, characterized in that the servomotor has a greater or smaller length on control and this motor is freely suspended between levers operating the cap and the diaphragm 20 located at the bottom. 10. Climate control system for a livestock shed, in particular a pigsty, provided with an extraction ventilation duct according to one or more of the preceding claims, characterized in that the speed of the fan and, via the servo motor, the position of the members on the ends of the tube are controlled by a micro-processor which is controlled by a signal from one or more temperature sensors in the livestock shed. 11. Climate control system according to claim 10, characterized in that the speed of the fan and the position of the members at the ends of the tube are controlled simultaneously. Livestock shed, in particular pigsty, provided with an extraction ventilation sleeve according to one or more of claims 1 to 9 and / or a climate control system according to claim 10 or 11. 840 3082 f-IIIs. Valve or piston for an exhaust ventilation duct according to any one of claims 1 to 9, characterized in that it has the shape of a cone. Eindhoven, October 5, 1984 8403082