FR3074637B1 - VENTILATION MODULE OF A VOLUME OF STORAGE OF AGRICULTURAL PRODUCTS IN GRAINS AND INSTALLATION EQUIPPED WITH SUCH A VENTILATION MODULE - Google Patents

Abstract

A ventilation module for a storage volume of agricultural products in grains comprising a radial fan (11) formed of a housing (111) housing the rotor (113) of the fan and having an axial inlet (115) and a tangential outlet ( 116). The module also comprises a tubular cell (12) axially housing the electric motor for cooling (125) the fan connected directly to an outside air intake pipe (11), an end (121) being connected to a pipe of supply (124) for the outside air and the other end (123) being connected to the housing (111). The motor (125) is connected by its axis (127) to the rotor (113). This fan module is intended to be installed in the grain storage volume (VS) to reduce noise during ventilation.

Description

Field of the invention

The present invention relates to a ventilation module consisting of a diffuser and a fan integrated in the storage volume of agricultural products in grains, with a fan integrated into the diffuser and all integrated into the volume of grains for therein. distribute pulsed air through the fan.

State of the art

It is necessary to break up storage volumes of grain-based agricultural products such as silos or heaps. The grains concerned are usually grains of cereals or similar products.

For this, we use ventilation systems consisting of a diffuser placed in the storage volume at the base of the storage hopper diffuser provided with perforations and covered with the bunch of granular products. These diffusers are supplied with forced air by a fan connected to the diffuser by a pipe passing through the wall of the hopper or the wall biting the storage area.

These fans must provide high flow rates and adequate pressure, so they are particularly noisy. This noise is bothersome for the personnel working near these areas or storage volumes and for the neighborhood because the noise intensity and the frequency are such that these fan noises are heard at distances of up to per kilometer. The ventilation ranges are often nocturnal to use the lowest temperatures.

Purpose of the invention

The object of the present invention is to develop a storage volume ventilation unit for agricultural grain products that makes it possible to reduce or even quench the operating noise of the ventilation system equipped with the ventilation unit.

DESCRIPTION AND ADVANTAGES OF THE INVENTION For this purpose, the subject of the present invention is a ventilation module of the type defined above, characterized in that it comprises a radial fan formed of a housing housing the rotor and having an inlet axial and a tangential outlet, a tubular cell axially housing the electric motor of the fan, and one end of which is connected to an external air supply pipe, the other end being connected to the fan housing, the motor being connected by its axis to the rotor of the fan, the ventilation module being intended to be installed in the grain storage volume and only its air supply pipe through the wall of the storage volume to open to the outside air.

This ventilation module has the advantage of integrating into the storage volume with its fan and the tubular cell housing the engine, upstream of the fan. The integration of the ventilation module completing the storage volume, that is to say in the grain mass ensures perfect sound insulation of the ventilation system so that the entire installation operates quietly.

The grain mass provides insulation by damping the vibration of the ventilation module, that is to say the noise generated by the operation of the fan rotor. The installation thus has the advantage of being particularly quiet both for the staff working near the storage volume which is a silo or a bunch of grains, and this silent operation also avoids disturbing the environment. or require the storage volume to be installed away from populated areas.

According to an advantageous characteristic, the tubular cell is formed of a central part leaving a peripheral passage, this central part being connected on the upstream side to a frustoconical inlet reducing its section to reach by its small base, the section of the feed pipe and downstream side. a frustoconical outlet connected by its small base to the axial inlet of the fan housing, the axis of the electric motor being connected to the axis of the fan rotor through the frustoconical outlet. This embodiment is particularly advantageous because simple and easy to integrate into a storage volume.

According to another characteristic, the electric motor of the fan is mounted axially in the tubular cell via damping supports. This avoids transmitting the vibration of the motor to the tubular cell and transmitting these vibrations via the supply pipe, suction side.

Advantageously and to complete the sound insulation of the ventilation module, the tubular cell is connected to the supply pipe by a connection incorporating a damper. Under these conditions, the supply pipe that opens out will not be an operating noise transmitter. The invention also relates to a ventilation system characterized in that it combines a ventilation module with a diffuser, the diffuser being formed of a cylindrical box with perforated double walls delimiting a cylindrical passage formed by the inner wall and a toric volume between the two walls, in which is integrated the fan housing of the ventilation module, the cylindrical box being installed in the bottom of the silo along its axis, above its outlet, and the tubular cell being inside storage volume and the feed pipe passing through the silo wall to open out.

This ventilation system is particularly effective because, on the one hand, it is installed at the base of the storage volume in the conical portion of the silo, above the outlet without impeding the flow of grain for the samples taken in the silo. According to another characteristic, the ventilation system is supported on the hopper bottom of the silo, along the axis of the silo above the outlet, leaving a space for the grains around the cylindrical diffuser and through its internal passage. by being pressed on the silo by legs. The invention also relates to a ventilation system for storage in a pile backed by a partition, this installation being characterized in that it combines a ventilation module with a perforated diffuser shaped pipe covered by the bunch of grains and a box covering the module fan housing placed in the bunch of grains.

drawings

The present invention will be described hereinafter in more detail with the aid of exemplary embodiments of a storage unit for storage of agricultural products in grain and ventilation systems equipped with such a ventilation group. , Figure 1 is a schematic view of the electric motor inserted in the air intake pipe itself inserted in the silo according to the invention, Figure 2 is a schematic view of a ventilation diffuser according to the invention installed in the bottom of a grain storage silo, FIG. 3 is an external partial view of the conical part hopper at the base of the storage silo of FIG. 3 and 2, FIG. 4 is a schematic view of a second type of ventilation installation of a storage volume of agricultural products in grains. This time in a pile leaning against a wall. Description of embodiments of the invention

According to Figure 1, the ventilation module 1 is composed of a radial fan 11 and a tubular cell 12 housing the electric motor 125 of the fan. The fan 11 is formed of a housing 111 receiving the rotor 113 supported by its axis 114 on the two bearings 112. The housing 111 has an axial inlet 115 and a tangential outlet 116.

The tubular cell 12 has a central portion 122 receiving the electric motor 125 in the axial position and leaving a peripheral passage 1221 for the intake air supplying the box 111. On the upstream side, the tubular cell 12 has a frustoconical inlet 121 forming the junction with the section of the supply pipe 124. Downstream side, the cell 12 has a frustoconical outlet 123 connecting the central portion 122 with the axial inlet 115 of the housing 111 of the fan 11.

The central portion 122 carries the motor 125 by supports 126 in the form of spokes. The supports 126 are connected to the wall of the central portion 122 by damping supports isolating the vibrations of the body 1251 of the motor of the wall of the cell 12. The axis 127 of the motor is connected to the axis 114 of the rotor 113. The body 1251 of the motor 125 and its cooling fins 1252 are swept by the air flow passing through the cell 12 and a part of which also passes through the motor 125. The motor 125 thus enclosed in the cell is nevertheless generously cooled, avoiding any threat of overheating.

The fan 11 feeds a diffuser 13 which is a box resistant to the grain load 131 provided with perforations so that the compressed air supplied by the fan 11 is thus distributed over the entire surface of the diffuser 13 to be injected into the mass of grains in which is immersed the whole fan-diffuser.

FIG. 1 schematically shows the integration of the ventilation module 1 in the VS grain storage volume, separated from the outside by a partition 14 which is the wall of the silo or, in the case of a pile storage, the wall that limits the end of the bunch of grains. The partition 14 has a passage 141 through which the air intake pipe opens to the outside E.

The direction of air circulation is represented by arrows F.

The portion of the ventilation module 1 downstream of the supply pipe 124 and a part thereof are integrated in the storage volume VS. This means that a portion of the supply pipe 124, the inlet pipe 12 and the fan 11 are embedded directly or indirectly in the grain mass of the storage volume VS.

Depending on the type of storage, silos or heaps, the fan 11 is installed in the diffuser 13 or at the inlet thereof and is thus directly or indirectly enveloped by the mass of grains that isolate and dampen the vibration / operating noise.

In the case of a silo, the diffuser 13 is combined with the ventilation module 1 and forms the ventilation system 2 which is fixed in the silo.

In the case of heap storage, the ventilation module 1 is connected at the output to a diffuser formed of one or more perforated pipes. The module 1 is then surrounded by a box 21 which is covered by the mass of grains so as to mechanically protect by its resistance to the load the fan 11 and, as the case may be, a part or the whole of the ventilation cell 12.

In all cases, the ventilation module 1 is remote from the partition 14 to be wrapped on all sides by the thickness of the mase grains.

The support of Module 1 on the infrastructure (the soil of the storage area in heaps or the wall of the silo) is preferably done with the interposition of a damping layer to cut the transmission of vibrations. It is the same passage 141 crossed by the supply pipe in the wall 14 with interposition of a seal 142 and preferably also the connection 1211 between the tubular cell 12 and the supply pipe 15.

Thus and in summary, the ventilation system 2 and in particular its ventilation module 1 are surrounded by a mass of grains which is particularly effective in absorbing vibrations and operating noise.

FIG. 2 schematically shows the section of a grain storage silo 3 composed of a cylindrical body 31 terminated at its lower part by a frustoconical hopper 32. The body 31 is supported by feet 33. The hopper 32 opens by its output 321 in an extraction device 34 in the form of a screw, not detailed.

Above this outlet and inside the silo 321 is fixed the ventilation installation 2 'figure 2 composed of the ventilation module 1 combined with a diffuser 13' installed in the ZZ axis of the silo 3.

The diffuser 13 '(FIG. 2) of this example is a cylindrical caisson 131 with double walls 132, 133 delimiting a toric volume 134. The walls 132, 133 are perforated except the top of the frustoconical 135 overlying this toric structure and on which press the column of grains. The inner passage 136 defined by the inner wall 133 is not covered by the frustoconical top 141. The fan 11 is housed in the toroidal volume 134 of the diffuser and directly supplied with air. The tubular cell 12 is external to this toric volume. The mechanical connection means between the module 1 and the diffuser 13 'are not detailed. The diffuser 13 'is supported by legs 137 on the wall of the hopper. The toroidal diffuser 13 'offers a large air / grain interface through its perforated inner and outer walls 132, 133.

For the evacuation of the grains, the diffuser 13 'does not constitute an obstacle because the grains flow along the outer wall 132 and in the cylindrical passage 136 formed by the inner wall 133. The frustoconical shape of the top 135 also guides the flow grains to flow outside the diffuser 13 ', which reduces the dynamic load on the diffuser 13'. The ventilation system 2 '(FIG. 2) mounted near the base of the silo 3 is in an effective position for the injection of the ventilation air into the entire mass of stored grains and the sound insulation of this installation by this mass of grains.

FIG. 3 is an external view of an alternative embodiment of the installation of FIG. 2 in which the air supply pipe 124 passes through the cylindrical portion 31 of the silo 3.

FIG. 4 shows the other mode of storage of the grains in a pile spread on an area bordered at one end by the partition 14, that is to say a wall traversed by a passage 141. The storage is equipped with a ventilation system 2 "composed of a ventilation module 1 housed partly in a box 21 resistant to the load.

The ventilation module 1 is formed of a fan 11 and a tubular cell 12 with the motor 125 of the fan 11. The cell 12 is connected to the outside (E) beyond the partition 14 by the pipe d 124. The casing 111 of the fan 11 is protected by the casing 21 in which opens the downstream outlet 123 of the cell 12, which does not need to be protected from the weight of the mass of grains as is the case of the housing 111 of the fan.

The outlet 116 (Figure 4) of the fan 11 is connected by a distributor 117 to one or more perforated pipes 15 constituting the diffuser 13 ". The perforated pipes 15 are oriented along the length of the pile of grains 4. Depending on the width of the pile 4 (in the direction perpendicular to the sheet of the drawing) there will be one or more parallel pipes connected to the distributor 117.

The extensible pipes 15 have their ends 151 connected to the distributor 117.

The distributor 117 is also connected, as the case may be, to perforated pipes for injecting air into the mass of grains VS on either side of the box 21.

NOMENCLATURE OF THE MAIN ELEMENTS I Ventilation module 2, 2 ', 2 "Ventilation system

21 Load-bearing casing Figure F 3 Silo 31 Cylindrical part 32 Hopper 321 Hopper outlet 33 Foot 34 Extraction device 4 Grain pile II Fan 111 Housing 112 Bearings 113 Rotor 114 Axis 115 Axial inlet 116 Tangential outlet 117 Dispenser 12 Tubular cell 121 Upstream inlet 1211 Supply pipe connection 122 Central part 1221 Peripheral passage 123 Downstream outlet 124 Supply pipe 1241 Wall passage 125 Electric motor 1251 Body 126 Motor support 127 Motor shaft 13, 13 ', 13 Diffuser 131 Perforated diffuser box 132 External diffuser wall 133 Diffuser interior wall 134 Toroidal volume 135 Frustoconical top 136 Inner passage 137 Leg 14 Storage space partition 141 Passage 142 Gasket 15 Perforated pipe forming a distributor 151 Rear end of the pipe 213 2131 torus diffuser 2132 housing 2133 exterior wall 2134 interior wall 2135 D ring volume frustoconical essus VS Storage volume / grain mass E Outside F Air flow direction ZZ Silo axis

Claims (7)

CLAIMS 1 °) Ventilation module of a storage volume of agricultural products in grains, with a fan connected to a diffuser integrated in the volume of grains to distribute the pulsed air by the fan, characterized in that it comprises: a radial fan (11) formed of a housing (111) housing the rotor (113) and having an axial inlet (115) and a tangential outlet (116), a tubular cell (12) axially housing the electric motor ( 125) of the fan (11), and * one end (121) of which is connected to a supply pipe (124) with external air, the other end (123) being connected to the housing (111) of the fan (11). ), the motor (125) being connected by its axis (127) to the rotor (113) of the fan, the ventilation module (1) being intended to be installed in the grain storage volume (VS) and only its air supply (124) passes through the wall (14) of the storage volume (VS) to outside air (E). 2) Ventilation module according to claim 1, characterized in that the tubular cell (12) is formed of a central portion (122) leaving a peripheral passage (1221), this central portion being connected upstream side to a frustoconical inlet (21) reducing its section to reach by its small base, the section of the supply pipe (124) and downstream side, a frustoconical outlet (123) connected by its small base to the axial inlet (115) of the housing (111) ) of the fan (11), the axis (127) of the electric motor (125) being connected to the axis (115) of the fan rotor (113) through the frustoconical outlet (123). 3 °) ventilation module according to claim 1 or 2, characterized in that the motor (125) is axially mounted in the tubular cell (12) by means of damping support. 4 °) ventilation module according to claim 1, characterized in that the tubular cell (12) is connected to the supply pipe (124) by a connection (1211) incorporating a damper. 5 °) Ventilation installation for storage in silo, characterized in that it combines a ventilation module according to any one of claims 1 to 3, to a diffuser (13, 13% the diffuser being formed of a box cylindrical (131) perforated double wall (132, 133) delimiting a cylindrical passage (136) formed by the inner wall (133) and a toric volume (134) between the two walls (132, 133), in which is integrated the housing (111) of the fan (11) of the ventilation module (1), the cylindrical box (131) being installed in the bottom (31) of the silo (3) along its axis (ZZ), above its outlet ( 321), and the tubular cell being inside the storage space (VS) and the supply pipe (124) passing through the wall (14, 31, 32) of the silo (3) to open out ( E). Ventilation device according to Claim 5, characterized in that the ventilation system (2) is supported on the hopper bottom (32) of the silo (3), along the axis (ZZ) of the silo. above the outlet (321) leaving a space for the grains around the cylindrical diffuser (IS ') and through its inner passage (136) being supported on the silo by legs (137). 7 °) Ventilation installation for storage in a pile (4) attached to a partition (14), characterized in that it combines a ventilation module (1) according to any one of claims 1 to 3, to a or a plurality of perforated diffusers (15) covered by the pile of grains (4) and, a load-resistant box (21) covering the housing (111) of the fan (11) of the module (1) placed in the pile of grains ( 4), the air supply pipe (24) passing through a passage (141) of the partition (14) bordering the bunch of grains (4).