专利摘要:
Apparatus for drying drying material (1), comprising a ventilation box (2) for receiving the material to be dried (1), wherein the ventilation box (2) is roofed over with a roof (3), the apparatus further comprising at least one fan (4) which fan (4) air can be sucked, wherein the sucked air is at least partially fed to a dehumidifier (5) and wherein by means of the at least one fan (4), the air finally through the ventilation box (2), from an initial area (15) to a End portion (16) of the ventilation box (2) is blown, wherein a switching flap (6) is provided, which is movable from a first position (7) to a second position (8), wherein in the first position (7) the air through the at least one fan (4) can be sucked in only from the ventilation box (2) and wherein in the second position (8) the air can be sucked in at least partially from outside the ventilation box (2). According to the invention a plurality of ventilation boxes are provided.
公开号:AT15376U2
申请号:TGM50029/2017U
申请日:2014-09-18
公开日:2017-07-15
发明作者:
申请人:Heutrocknung Sr Gmbh;
IPC主号:
专利说明:

description
DEVICE FOR DRYING DRYING GOODS OF THE INVENTION
The present invention relates to a device for drying of drying material, comprising a ventilation box for receiving the material to be dried, wherein the ventilation box is roofed with a roof, the device further comprising at least one fan through which fan air is sucked, wherein the sucked air is at least partially fed to a dehumidifier to dehumidify the air, and wherein by means of the at least one fan, the air is finally blown through the ventilation box, from an initial area to an end portion of the aeration box, wherein the Trocknungsgut between the starting area and end portion on a through the air an implosible box surface can be arranged, wherein a Umschaltklappe is provided which is movable from a first position to a second position, wherein in the first position, the air is sucked through the at least one fan only from the ventilation box to a closed Luftkre form in the device, and wherein in the second position, the air is at least partially sucked from outside the ventilation box.
STATE OF THE ART
In the drying of Trocknungsgut, especially hay, which can be used in agriculture as an ideal feed for cattle, it is known to dehumidify air and to blow through the Trocknungsgut. For this purpose, the drying material is placed in a ventilation box. The air is drawn in via a fan, fed to a dehumidifier and then blown into the ventilation box. To accelerate drying, the air used for drying is heated, for which, for example, an electric heater or a wood chip furnace is used. The disadvantage here, however, is the high energy input that goes with the drying. In particular, when very large amounts of air are required for drying, the drying can sometimes not be carried out economically.
GB 2463747 A, which relates to a heating and ventilation system for perishable goods storage, is known from the prior art. Here, air is blown through a channel by means of a fan to set a desired humidity and temperature. The fan is disposed in a housing having a closable inlet for selectively aspirating air from outside or inside the reservoir. Furthermore, flaps are provided in the memory, from which air can escape to the outside, so as not to let the pressure in the memory become too large. Furthermore, heaters are provided to dry air that has been sucked from the outside.
Furthermore, US 1989530 A is known from the prior art, which relates to a device for storage of hay, wherein a drying can be done. The hay is placed in a metal container, the hay rests on a grid with rods. Air is blown through the grate by means of a blower which has previously been cooled or heated in a targeted manner. The container has vertically spaced doors / openings that can be opened to mix fresh air with the warmed air.
OBJECT OF THE INVENTION
It is therefore an object of the present invention to provide an improved apparatus and an improved method that allow the drying of drying material with low energy input and at the same time high air volumes or high drying effect.
PRESENTATION OF THE INVENTION
For drying of drying material, preferably hay, the drying material is placed in a ventilation box between an initial area and an end portion of the ventilation box. The ventilation box protects the material to be dried from the weather outside of the ventilation box and is accordingly equipped with a roof. In this case, the material to be dried is arranged on an inflatable box surface, wherein the inflatable box surface does not necessarily have to be a horizontal surface but can also be a vertical surface or an inclined surface with an inclination between the horizontal and the vertical. Air for drying is sucked in with at least one fan and at least partially fed to a dehumidifier. Subsequently, the air is blown with the at least one fan through the ventilation box, from the starting area to the end area.
The invention is now based on the idea to exploit any existing heat sources targeted and in a controlled manner to heat the air for drying. In particular, air coming from outside, i. from outside the ventilation box, is sucked in, be warmed with existing heat sources. Preferably, solar energy is used for heating the air sucked from the outside. However, this air is only supplied to the dehumidifier or an air circuit in the ventilation box, if it is warm enough, otherwise there would be a cooling of the air temperature in the ventilation box.
Therefore, it is in a device for drying Trocknungsgut, comprising a ventilation box for receiving the Trocknungsguts, wherein the ventilation box is roofed with a roof, the device further comprising at least one fan through which fan air is sucked, wherein the sucked air is at least partially fed to a dehumidifier to dehumidify the air, and wherein by means of the at least one fan, the air is finally blown through the ventilation box, from an initial area to an end portion of the aeration box, wherein the Trocknungsgut between the starting area and end portion on a through the air According to the invention, it is provided that a switchover flap is provided which can be moved from a first position to a second position, wherein in the first position the air can be sucked in by the at least one fan only from the ventilation box form an air circuit in the device, and wherein in the second position, the air is at least partially sucked from outside the ventilation box.
Preferably, to control the switchover flap, an outside temperature, i. the temperature of the air drawn from outside the ventilation box, and / or an internal temperature, i. the temperature of the air in the aeration box, and / or the difference between outside temperature and inside temperature used. Accordingly, it is provided according to the invention in a method for drying drying material that a device according to the invention is used and the material to be dried is introduced into the ventilation box and that an outside temperature of the air suckable from outside the ventilation box is measured, with an internal temperature of the air in the ventilation box , is preferably measured in the end region and wherein the switching cap is moved in dependence on the outside temperature and / or the inside temperature and / or the difference between the outside temperature and the inside temperature from the first position to the second position and vice versa. Embodiments in which only the outside temperature or only the inside temperature is used to control the switching flap can prove to be particularly simple in construction.
In order to increase the internal temperature or not to drop, it is provided in a preferred embodiment of the method according to the invention, that the changeover flap is moved to the second position or held in the second position when the outside temperature is greater than or equal to an outside temperature threshold / or if the difference between outside temperature and inside temperature is greater than or equal to a positive differential temperature threshold. In principle, it is of course also conceivable that the switchover flap is moved to the second position or held in the second position when the internal temperature is less than or equal to a certain internal temperature threshold.
In experiments outside temperature thresholds and positive Differenztemperaturschwellwerte were determined, which give a rapid rocking of the internal temperature. Accordingly, it is provided in a particularly preferred embodiment of the method according to the invention that the outside temperature threshold is between 22 ° C and 27 ° C, preferably at 25 ° C and the positive Differenztemperaturschwellwert between 2 ^ 0 and 5 ° C, preferably at 3 ° C. It should be emphasized again in this context that it is sometimes sufficient for a rocking of the internal temperature, if only the difference between the outside temperature and the inside temperature is greater than or equal to the positive Differenztemperaturschwellwert. For example, in experiments, a build-up of the internal temperature could be achieved even at outside temperatures that were significantly lower than the specified values for the outdoor temperature threshold, e.g. from an internal temperature of ~ 2 ° C was assumed.
Conversely, the Umschaltklappe also allows specifically to suck in cool air from the outside, if necessary to dehumidify and blow into the ventilation box when the temperature in the ventilation box should be targeted lowered. Therefore, in a preferred embodiment of the method according to the invention, it is provided that the switchover flap is moved to the second position or held in the second position when the difference between the outside temperature and the inside temperature is less than or equal to a negative differential temperature threshold value. Of course, it is of course also conceivable in particularly simple embodiments that the switching flap is moved to the second position or held in the second position when the internal temperature is greater than a certain internal temperature threshold and / or the outside temperature is lower than a certain outside temperature threshold.
In experiments negative Differenztemperaturschwellwerte were determined, which ensure a rapid reduction of the internal temperature. Accordingly, it is provided in a particularly preferred embodiment of the method according to the invention that the negative Differenztemperaturschwellwert between -5 ° C and -2ΧΪ, preferably at -3 ^.
In order to optimally use solar energy for heating the air sucked from outside of the ventilation box, it is provided in a preferred embodiment of the device according to the invention that under the roof an air duct is provided to the sucked in the second position from outside the ventilation box under air to conduct along the roof and to allow heat transfer between the roof and the air. Through the roof, a large area can be provided in a structurally simple way, which is illuminated by the sun. Accordingly, the air sucked from the outside can be warmed up very well even in moderate sunlight, before it is fed to the dehumidifier.
In order to use the solar energy efficiently, a good heat conduction of the roof is advantageous. Accordingly, sheet metal is a good material choice. In addition, trapezoidal sheets provide a structurally simple and relatively inexpensive way for the formation of a roof. Therefore, it is provided in a preferred embodiment of the device according to the invention that the roof is designed as a sheet metal roof, preferably made of trapezoidal sheets.
At sufficiently high outside temperatures or temperatures outside of the ventilation box, it is sufficient to suck the air exclusively from the outside or via the air duct under the roof to still realize a sufficiently high temperature in the ventilation box. Accordingly, it is provided in a preferred embodiment of the device according to the invention that in the second position, the air can be sucked only from outside the ventilation box.
In order to enable a comfortable and automatable moving the changeover, it is provided in a preferred embodiment of the device according to the invention that a cylinder, preferably an electric cylinder is provided to the changeover between the first position and the second position back and forth to move. Selbstver of course also differently operated cylinders are conceivable, such as hydraulic or pneumatic cylinder.
Depending on the relative humidity of the air sucked from the outside, it can sometimes be dispensed with to dehumidify this air by means of the dehumidifier. Typically, the dehumidifier does not have to be switched on until the outside air intake has a relative humidity of more than 50%. Here, a structurally simple solution is always to lead the entire intake air through the dehumidifier and turn on the dehumidifier only when needed. This is independent of where the change-over door is located, i. even if no air from the outside, but only from the ventilation box is sucked. Therefore, it is provided in a preferred embodiment of the device according to the invention, that the entire sucked air can be supplied to the dehumidifier.
The dehumidifier has an evaporator in which refrigerant is vaporized by the heat of the sucked air, whereby the sucked air is cooled again below the dew point. Accordingly, water condenses on the cold surface of the evaporator and drips or drips off the evaporator. In order to be able to dehumidify as much as possible the entire sucked air, it is provided in a preferred embodiment of the device according to the invention that the dehumidifier comprises an evaporator and a condenser, wherein the air dehumidifier supplied air at least partially, preferably completely feasible through the evaporator ,
It should be noted that this type of dehumidification can also be used to selectively cool the drying material located in the ventilation box by dehumidifying and cooling the air after it has passed through the evaporator, without subsequent heating is injected directly into the ventilation box or in the beginning of the ventilation box.
Conversely, it is for a quick drying advantage to warm the dehumidified air before it is blown into the ventilation box. Therefore, it is provided in a preferred embodiment of the method according to the invention that the air, after it has been passed through the evaporator, is heated.
If the dehumidified air to be warmed up, this is done in a structurally simplest way by the dehumidified air is passed through the condenser, in which the refrigerant condenses and thereby releases latent heat, whereby the capacitor can be used as a heat source. Therefore, it is provided in a preferred embodiment of the device according to the invention, that the evaporator and condenser are arranged such that the air supplied to the dehumidifier air through both the evaporator and through the condenser is feasible. Thus, even in this case, an already existing heat source, namely the condenser, be used for the heating of the sucked or be blown into the ventilation box air.
Moreover, it is of course possible to provide a further heat source for additional heating of the dehumidified air. In order to realize a particularly compact arrangement, it is provided in a preferred embodiment of the device according to the invention that a heat source is arranged between the evaporator and the condenser in order to additionally heat the air which has passed through the evaporator.
However, even in this case, there is no need to rely on additional heating, e.g. an additional electric heater, be resorted to. This is because the dehumidifier includes a compressor to compress the refrigerant evaporated in the evaporator. Since the compressor gives off heat, so is the compressor as an additional heat source, which can also be conveniently accommodated between evaporator and condenser, without significantly affecting the flow of air from the evaporator to the condenser. Therefore, it is provided in a preferred embodiment of the device according to the invention that the dehumidifier comprises a compressor which at least partially, preferably completely forms the heat source. This also contributes to the utilization as possible of all existing heat sources for the heating of sucked air.
In order to control the drying process, it is desirable to be able to adjust the air flow. This can basically be done by controlling the fan, whereby the amount of sucked air and thus the amount of air blown into the ventilation box can be regulated. It should be noted that the density of aufgebbenem drying material may vary, which is accompanied by a different resistance for the air blown into the ventilation box. It is therefore provided in a preferred embodiment of the device according to the invention that the at least one fan has a speed control to set the intake air quantity to a predetermined value. In this way, in the case of hay, for example, quantities of intake air or air throughputs of 200 m3 / h per square meter of pit area, mB2, to 600 m3 / h / mB2, preferably 400 m3 / h / mB2, can be set as the drying material may have a density of typically 100 kg / m3 to 250 kg / m3.
Preferably, the hay is substantially loose in the aeration box, i. especially not in the form of round bales. Of course, it is also possible to dry the hay in a round bale shape. In this case, the inflatable box area is limited to the area on which the round bale rests or rest. This can preferably be realized in such a way that in each case a round bale to be dried is arranged above an opening in the starting region of the ventilation box, the air used for drying being blown through the opening into the ventilation box or directly onto the respective round bale. The opening may be made as a circular hole and is adapted to the diameter of the round bales, i. the diameter of the opening substantially corresponds to the diameter of the round bale and is therefore e.g. between 1.2 m and 2 m. So that the round bale does not fall into the opening, the opening can be covered, for example, with a grid. Accordingly, in this case, air flow rates of 850 m3 / h to 2000 m3 / h per opening or per round bale arise.
An easy-to-implement way to control the speed of the fan but also to the performance of the dehumidifier, this being essentially determined by the performance of the compressor, provide frequency converter. It is therefore provided in a preferred embodiment of the device according to the invention that are provided to control the at least one fan and / or the dehumidifier frequency.
In order to measure the amount of air sucked, it is provided in a preferred embodiment of the device according to the invention that a sensor is provided for measuring the velocity of the sucked air, which is preferably arranged in the dehumidifier behind the evaporator. The measurement result can be used in the sequence as a control variable for controlling the at least one fan. The arrangement of the sensor behind the evaporator has the advantage that the evaporator provides some protection for the sensor from dust. In addition, this sensor arrangement proves to be particularly favorable when always the entire amount of air sucked is supplied to the dehumidifier, even if it is not operated, since the dehumidifier represents a defined cross-sectional area through which the sucked air must pass. Since this cross-sectional area is known, it can be concluded by measuring the air velocity in the dehumidifier directly on the amount of air sucked in per time.
Furthermore, it is provided in a particularly preferred embodiment of the device according to the invention that a sensor for measuring the pressure of the injected air is arranged in the initial region. The possible monitoring of the pressure in the initial region or of the resulting differential pressure between the starting region and the end region can be used, for example, to ensure that a certain permissible maximum pressure in the initial region or a certain maximum permissible pressure difference is not exceeded. This can occur if the density of the material to be dried is too high and affects the air flow too much. If appropriate, the at least one fan can thus be regulated back accordingly.
In order to monitor and automate the drying process, it is provided in a preferred embodiment of the device according to the invention that sensors for measuring the temperature and humidity are provided both in the initial region and in the end region. As stated above, it can be decided, by comparison with the outside temperature or the temperature of the air which can be drawn from outside the ventilation box, whether the change-over flap should be moved to a position other than the current position.
In order to process the signals of all sensors for automation of the drying process, it is provided in a preferred embodiment of the device according to the invention that a control unit, which is preferably designed as a programmable logic controller, is provided by means of which at least one Fan, the dehumidifier and the changeover flap can be controlled and / or regulated. The design as a programmable logic controller makes it possible, for example, to take into account the amount of drying material currently to be dried and to specify or adjust threshold values for the inside temperature, outside temperature, air humidity and air flow rate.
The device according to the invention can be extended by more ventilation boxes, which allows an interval drying of the drying material in the different ventilation boxes. That The sucked air is preferably not blown into all ventilation boxes simultaneously, but always in a ventilation box, after a certain predetermined time the air is directed to the next ventilation box or blown into the next ventilation box. Therefore, it is provided in a preferred embodiment of the device according to the invention that a plurality, preferably five ventilation boxes are provided, wherein air guiding means are provided to selectively direct the air to a specific ventilation box.
For this purpose, an air duct to the beginning of each ventilation box is provided and at least one air deflector to selectively direct the air to the desired ventilation box.
Of course, the at least one air deflector can be controlled by means of the control unit.
By the drying material is divided into two or more ventilation boxes, sometimes shorter drying times can be achieved than when drying the same amount of material to be dried in only one ventilation box. The reason for this is, on the one hand, that the material to be dried can be arranged less densely in the individual ventilation boxes than in a single ventilation box.
On the other hand, it has been shown that plants, after they have been cut, stored water via capillary action - at least over a period of time - continuously feed the leaves in order to possibly still be able to bring about an emergency. This, in turn, causes, in a first time interval, in which the hay, e.g. in a further aeration box is not dried, an increased moisture forms in the leaves. If now in a subsequent second time interval, the hay is dried in this further ventilation box by blowing air, especially in a relatively short initial period of this second time interval, an increased amount of moisture is removed from the hay. In other words, by waiting a long time for the first time interval and then drying, the same drying effect is achieved in the relatively short initial time period of the second time interval as if air had been continuously blown into the further aeration box for drying over the entire first time interval.
Conversely, during the second time interval no air is now blown into a first and / or second and / or third and / or fourth and / or fifth and / or even beyond going - ventilation box, so that increased moisture in the leaves of the hay in this ventilation box or these ventilation boxes can form and so on.
It should be noted that too long a time interval in which no air is blown into a certain ventilation box, can lead to the hay or drying material to be dried in this ventilation box lowers and undesirably compacted. For this purpose, experiments have shown that in the intervalwise drying the time intervals should be no longer than two hours without injected air.
In experiments with hay time savings of up to 40% could be achieved by interval drying.
Of course, it is also conceivable to dry different drying material in the different ventilation boxes. Examples of different drying material in the various ventilation boxes would be: loose hay; Hay in round bale form; wood chips; Hop; Grain; Corn; Herbs, in particular for herbal teas; biogenic raw materials for the production of biogas; Slaughterhouse waste or building materials.
As already mentioned, by means of the device according to the invention or by means of the method according to the invention, a wide variety of drying goods can be dried, preferably organic drying goods. Accordingly, the invention provides the use of a device according to the invention for drying hay. In this way, the nutrients in the hay can be obtained, especially if the hay is already retracted with a residual moisture. The hay retains its aromatic scent, which has an advantageous effect on the feeding of dairy cows, because the animals eat a lot of this hay and as a result have more energy, are healthier and produce more milk.
Likewise, the use of a device according to the invention for drying food is provided according to the invention. As a special case of hops may be considered or according to the invention the use of a device according to the invention for drying hops provided. The drying according to the invention also allows in this case a maximum preservation of the aroma of the food or the hops.
BRIEF DESCRIPTION OF THE FIGURES
The invention will now be explained in more detail with reference to an embodiment. The drawings are exemplary and are intended to illustrate the inventive idea, but in no way restrict it or even reproduce it.
1 shows a schematic view of a device according to the invention for drying hay. FIG. 2 shows a schematic view of an air dehumidifier of the invention
Device of Fig. 1
WAYS FOR CARRYING OUT THE INVENTION
In the schematic view of Fig. 1, an apparatus according to the invention for drying drying material is shown, wherein the material to be dried is hay 1 in this case. The hay 1 is arranged in a ventilation box 2 between an initial region 15 and an end region 16, wherein in the illustrated embodiment the hay 1 is divided into a total of five ventilation boxes 2. The ventilation boxes 2 are roofed with a roof 3, so that the hay 1 is protected from the weather.
In each ventilation box 2, the hay 1 rests on a box surface 22. The box surface 22 can be flowed in with air by the box surface 22 being realized, for example, by a structural steel grid (not shown), which rests on grate carriers (not shown) and is arranged above a base 23 at a certain distance, for example 40 cm. As a result, an air channel 21 is formed in the initial region 15 through which air can be blown onto the box surface 22 or into the ventilation box 2.
In the illustrated embodiment, the air can optionally be supplied to a specific ventilation box 2. For this purpose, each ventilation box 2 is equipped with a louver 20 which either closes the box surface 22 or directs the air onto the box surface 22. The louvers 20 and the air duct 21 therefore function as air guiding means for selectively directing the air to a specific ventilation box 2.
In order to blow the air into or through the ventilation boxes 2, the device shown in Fig. 1 has a fan 4, wherein the arrows in Fig. 1 symbolize possible air flows. The air to be injected into the ventilation boxes 2 is first sucked in by means of the fan 4, wherein preferably the entire sucked-in air is sucked through a dehumidifier 5, in which dehumidifier 5 the air is dehumidified.
According to the invention, the device has a switching flap 6, which is arranged in the end region 16 and can be moved by means of an electric cylinder 10 between a first position 7 and a second position 8 back and forth. In the first position 7 shown in FIG. 1, the switching flap 6 causes air to be sucked in only from the ventilation boxes 2. This air is subsequently fed to the dehumidifier 5 and blown back into a selected ventilation box 2. That in this case, there is a closed air circuit in the device.
In the second position 8, however, which is indicated in Fig. 1 by the dashed line, the air is preferably sucked completely from the outside or from outside the ventilation boxes 2. Specifically, this is an air duct 9 formed under the roof 3. By following the sucked in air from the outside under the roof 3, a heat transfer between this air and the roof 3 is favored. If the roof 3 is warm due to the sunlight, in this way the air drawn in from outside - ultimately by solar energy - can be warmed up. In order to be able to use the solar energy particularly efficiently, a good heat conduction of the roof 3 is advantageous, for which reason the roof 3 is preferably made of sheet metal, particularly preferably of trapezoidal sheets. The switching flap 6 thus makes it possible to use air which can be sucked in from the outside in a targeted manner in order to achieve a desired temperature of the air in the ventilation box 2 or in its starting area 15 and / or end area 16, i. to achieve a desired internal temperature.
To control the internal temperature and the humidity in the aeration box 2 and the drying progress sensors 17 are provided in the initial region 15 and 16 in the end. Moreover, a temperature sensor 24 is provided in the air passage 9 in front of the switching door 6 to measure an outside temperature of the outside sucked air. Of course, embodiments are conceivable in which instead of the temperature sensor 24, a sensor 17 is used to also measure the relative humidity of the air sucked from the outside directly in the air duct 9. Outdoor temperature and indoor temperature can be compared.
If now, for example, the air in the ventilation box 2 are warmed to allow faster drying, the outside temperature with the internal temperature, preferably in the end region 16, compared. If the difference between outside temperature and inside temperature is greater than a predefinable positive differential temperature threshold, e.g. 3 ^, the change-over flap 6 is brought into the second position 8 to specifically suck in warm air from outside the ventilation box 2.
It should be noted that depending on the relative humidity of the air sucked from the outside can sometimes be waived to dehumidify this air by means of the dehumidifier 5. Typically, the dehumidifier 5 must be turned on only at a relative humidity of the externally drawn air of more than 50%.
On the other hand, if the difference between the outside temperature and the inside temperature is not high enough or even negative, the switching flap 6 is brought into the first position 7, in order to avoid a cooling of the air inside the ventilation box 2.
However, the air in the ventilation box 2 or the Trocknungsgut course also be cooled by the Umschaltklappe 6 is brought to the second position 8, when the difference between the outside temperature and the inside temperature is negative.
If the air sucked in from the outside is not warm enough or if the internal temperature should be raised more quickly, further, already existing heat sources can be used for heating the air. For this purpose, offers the dehumidifier 5, which is shown schematically in Fig. 2, wherein the arrow indicates the flow direction of the air. The dehumidifier 5 has an evaporator 11 in which refrigerant (not shown) is vaporized by the heat of the sucked air. As a result, the sucked air is cooled below the dew point, and water condenses on the cold surface of the evaporator 11, from where it runs off or drips. Furthermore, the dehumidifier 5 has a condenser 12, in which the refrigerant condenses and thereby releases latent heat. Thereby, the condenser 12 can be used as a heat source for heating the dehumidified air, in which the air, after having passed the evaporator 11 and dehumidified, is also sucked through the condenser 12.
Moreover, the dehumidifier 5 comprises a compressor 13 for compressing the refrigerant evaporated in the evaporator 11. Since the compressor 13 in this case gives off heat, the compressor 13 is also suitable as an additional heat source, which can also be arranged conveniently between the evaporator 11 and the condenser 12, without significantly affecting the flow of air from the evaporator 11 to the condenser 12, see FIG ,
By using the condenser 12 and the compressor 13 as - already existing - heat sources, the internal temperature can be raised even if the outside temperature is lower than the internal temperature. In this case, the switching door 6 is moved to the first position 7 and can be left there, e.g. as long as the internal temperature does not exceed a predefinable internal temperature threshold.
Experiments have shown that targeted use of the capacitor 12 and the compressor 13 as already existing heat sources to additional heat sources, such as in the form of additional electrical heating, can be dispensed with entirely and still excellent drying results and high drying effects can be achieved.
Another point to consider in controlling the drying process is the air flow rate. The air flow rate can be influenced by a control of the fan 4, i. the amount of sucked air and thus the amount of air blown into the ventilation boxes 2 can be regulated. Normally, air flow rates or amounts of intake air of 200 m3 / h per square meter of pit area 22, mB2, to 600 m3 / h / mB2, preferably 400 m3 / h / mB2 should be set. It should be noted that the density of the hay 1 can vary - typically between 100 kg / m3 to 250 kg / m3 -, whereby a different resistance for the blown into the aeration boxes 2 air is accompanied. Accordingly, the power or the rotational speed of the fan 4 must be controllable, for which purpose according to the invention frequency converters are provided (not shown). Frequency converters are also preferably used to control the power dehumidifier 5 or the compressor 13 of the dehumidifier 5.
To determine the air flow or the amount of air sucked in a sensor 18 is provided for measuring the velocity of the sucked air, which is preferably arranged in the dehumidifier 5, behind the evaporator 11. Since the cross-section of the air dehumidifier 5 through which the air flows is known, the air flow rate results directly from this.
Furthermore, in order to monitor the pressure of the air which is blown into the ventilation boxes 2, a pressure sensor 19 is arranged in the starting area 15. The possible monitoring of the pressure in the starting region 15 or of the resulting differential pressure between the starting region 15 and the end region 16 can be used, for example, to ensure that a certain permissible maximum pressure in the starting region 15 or a certain maximum permissible pressure difference is not exceeded. This can occur when the density of the hay 1 is too high and affects the air flow too much. Optionally, therefore, the fan 4 can be regulated back accordingly.
All control and control operations are controlled in the embodiment shown by a control unit 14, see Fig. 1, which is designed as a programmable logic controller. The control unit 14 processes the signals of all sensors 17, the temperature sensor 18 and the pressure sensor 19. The execution of the control unit 14 as a programmable logic controller also makes it possible to take into account the current amount of hay 1 to be dried and thresholds for indoor temperature, outdoor temperature To specify or adjust air humidity and air flow. Based on this data or information controls the control unit 14, the switching valve 6 and regulates the performance of the fan 4 and the breather 5. In addition, the control unit 14 can control the louvers 20 to an interval drying of the hay 1 in the allow individual ventilation boxes 2. In this way, the drying of the hay 1 is highly automated and optimized.
REFERENCE LIST 1 Hay 2 Ventilation box 3 Roof 4 Fan 5 Dehumidifier 6 Reversing door 7 First position of changeover door 8 Second position of changeover door 9 Air duct 10 Electric cylinder 11 Evaporator 12 Condenser 13 Compressor 14 Control unit 15 Start area 16 End area 17 Sensor for measuring temperature and humidity 18 Sensor for measuring the velocity of the air sucked in 19 Pressure sensor 20 Air deflector 21 Air duct in the starting area 22 Pit surface 23 Ground 24 Temperature sensor
权利要求:
Claims (8)
[1]
claims
1. Device for drying drying material (1), in particular hay, comprising a ventilation box (2) for receiving the item to be dried (1), wherein the ventilation box (2) with a roof (3) is covered, the device further comprising at least one fan (4) through which fan (4) air can be sucked, wherein the sucked air at least partially a dehumidifier (5) can be supplied to dehumidify the air, and wherein by means of the at least one fan (4), the air finally through the ventilation box (2), from an initial region (15) to an end region (16) of the ventilation box (2) is blown, wherein the drying material (1) between the start region (15) and the end region (16) on an inflatable by the air box surface (22) can be arranged, wherein a Umschaltklappe (6) is provided, which is movable from a first position (7) to a second position (8), wherein in the first position (7), the air through the at least one fan (4) only a us the ventilation box (2) is sucked to form a closed air circuit in the device, and wherein in the second position (8) the air is at least partially sucked from outside the ventilation box (2), characterized in that a plurality, preferably five ventilation boxes (2) are provided, wherein air guiding means (20, 21) are provided to selectively direct the air to a specific ventilation box (2), that further comprises a control unit (14), which is preferably designed as a programmable logic controller, is provided , by means of which the at least one fan (4), the dehumidifier (5) and the changeover flap (6) are controllable and / or controllable and that the air guiding means comprise at least one air guiding flap (20) which can be controlled by means of the control unit (14) is.
[2]
2. Apparatus according to claim 1, characterized in that for each ventilation box (2) a louver (20) is provided, which by means of the control unit (14) is controllable.
[3]
3. Device according to one of claims 1 to 2, characterized in that the at least one air deflector (20) by means of the control unit (14) is controllable in such a way to dry the Trocknungsgut (1) in the different ventilation boxes (2) at intervals ,
[4]
4. Device according to one of claims 1 to 3, characterized in that the at least one air deflector (20) by means of the control unit (14) is controlled in such a way to blow the air only in one of the ventilation boxes and after a certain predetermined Time to direct the air to the next ventilation box and blow into it.
[5]
5. Device according to one of claims 1 to 4, characterized in that the at least one air deflector (20) by means of the control unit (14) is controllable to the Trocknungsgut (1), in particular hay, in one of the ventilation boxes (2 ) during a first time interval and to dry in a subsequent second time interval by blowing air into this aeration box (2).
[6]
6. Apparatus according to claim 5, characterized in that the first time interval is a maximum of 2 hours.
[7]
7. Device according to one of claims 1 to 6, characterized in that the different ventilation boxes (2) are provided for drying of different drying material (1).
[8]
8. Device according to one of claims 1 to 7, characterized in that a sensor (18) is provided for measuring the speed of the sucked air, which is arranged in the dehumidifier (5) behind the evaporator (11). For this 1 sheet drawings
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同族专利:
公开号 | 公开日
DE202014010983U1|2017-03-02|
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引用文献:
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法律状态:
优先权:
申请号 | 申请日 | 专利标题
AT3912013|2013-11-22|
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