RU2249935C2 - Method and apparatus for thermal disinfecting of lupine seeds from anthracnose pathogen - Google Patents

Abstract

FIELD: agriculture, in particular, methods used in plant growing.

SUBSTANCE: method involves heating seeds to temperature of 60-75°C by providing convective supplying of heat into flow of heat-carrier blown through seed layer and wetting heat-carrier to wettability of 79-84%; providing treatment in layer having thickness not in the excess of 0,10-0.15 m; determining treatment time from the following dependence: τ_opt=0.016(T_hc-50)10^{[(341+1.74Ws)/(38+0.62Wc)]-0.1Thc}, cm, where T_hc is temperature of heat carrier, °C, W_s is relative wettability of seeds, %. Apparatus has chamber with recirculation circuit including heater, fan, and wetting device adapted for wetting of heated heat-carrier and positioned at suction line of recirculation circuit, downstream of heater immediately before suction window of fan. During operation of apparatus, water steam is supplied into suction line of recirculation circuit and involved together with heated heat-carrier by fan, is thoroughly mixed and further blown through seed layer. Used heat-carrier is newly supplied into suction line of recirculation circuit.

EFFECT: intensified disinfecting procedure, increased disinfecting efficiency and provision for keeping seeding qualities of seeds.

2 cl, 5 dwg, 1 tbl

Description

The invention relates to agriculture and may find application in crop production for the disinfection of lupine seeds from the pathogen anthracnose.

A known method of thermal disinfection of lupine seeds from the pathogen anthracnose (Savchenko LF Laboratory method of thermal disinfection of lupine seeds from the pathogen anthracnose. All-Russian Research Institute of Phytopathology. Big Vyazma. 1997). [1], including heating of lupine seeds with a moisture content not exceeding 14% to a temperature of 70 ° C with convective or conductive heat supply and subsequent holding at the reached temperature for 7 hours, with a low contamination of seeds with anthracnose, and keeping at a given temperature for 24 hours, with high infection with anthracnose.

The known method is implemented in the work of known devices: drying cabinets, shaft dryers SZSh-16, M-819 and others. This method has the following disadvantages.

So, when heating the coolant, for example, from 20 to 70 ° С before blowing it through the seed layer in the shaft dryers, its relative humidity according to the J-d diagram of moist air decreases significantly: from 50 ... 60 to 5 ... 10%.

When exposed to during the heat treatment of such a coolant on lupine seeds with a moisture content of up to 14%, they intensively lose moisture. Moisture exchange between heating to 70 ° C with the coolant and the seeds practically stops when the moisture content of the seeds approaches 2.0-2.5%. At this moment, the state of thermodynamic equilibrium sets in, the partial pressure at the surface of the seeds and in the surrounding coolant equalizes.

Thus, in the known method, the moisture content of the seeds in a short time - 60-70 minutes is reduced from the original 14% to close to equilibrium 2.0-2.5%. The drying rate at individual time intervals reaches 0.28% / min. For large-seeded crops, which is lupine, this can cause undesirable changes - "hard stone", the destruction of the outer shell. As a result, macro- and microcracks occur on the surface of the seeds. As a result, their sowing qualities are reduced.

In addition, the implementation of the known method using shaft grain dryers, where the thickness of the seed layer, purged by the coolant, is usually 0.2 ... 0.5 m or more, does not ensure uniform heating of seeds over the thickness of the layer, which affects the efficiency of heat treatment.

Even more uneven is the heating of the seeds when used for heat treatment of drying ovens. In this case, seed treatment is usually carried out in bags. Seeds located closer to the walls of the sacs warm up faster and dry out. Seeds located in the deeper layers, due to the low heat conductivity of the seeds, warm up much more slowly, which also affects the efficiency of heat treatment.

Of those known to the claimed technical essence, the closest method is to heat the seeds to a predetermined temperature by convective heat supply in a heat carrier stream, blown through a layer of seeds, and then keep them at the temperature reached for a certain period of time, while the heat carrier heated to a given temperature is moistened to the content it contains 60 ... 90% moisture before blowing it through a layer of seeds. The thickness of the seed layer is controlled so that the subsequent heating of the seeds is uniform (WO 97/38734, 10.23.1997), the prototype, and the temperature of the coolant is selected depending on the content of the initial moisture content of the seeds and the type of pathogen [2].

However, the effectiveness of disinfection and sowing quality of seeds during the heat treatment is significantly affected by the duration of the heat exposure and the thickness of the blown layer.

The duration of the heat treatment, in turn, depends on the temperature of the coolant, the initial moisture content of the seeds and the thickness of the blown layer.

The results of experiments on thermal disinfection of seeds at an initial moisture content of lupine seeds from 6 to 15%, in a thin layer with a thickness not exceeding 0.10 ... 0.15 m, and a heating medium temperature of 65 ° C are shown in Fig. 1.

For example, in the variant with a coolant temperature of 65 ° C and seed moisture during the entire treatment period at the level of 15%, the duration of the heat treatment until an almost complete disinfecting effect is achieved, provided that the sowing qualities of the seeds are preserved, is about 4 hours, with a seed moisture content of 10%, this time period increases up to 9.5 hours, and with a moisture content of 6% - up to 21 hours.

The results of experiments on seed disinfection at an initial seed moisture of 10-12% in a thin layer with a thickness not exceeding 0.10-0.15 m, and a coolant temperature varying from 50 to 75 ° C, are shown in Fig.2.

It was found that with an increase in the temperature of the coolant, for example, from 60 to 75 ° C, the duration of the heat treatment until an almost complete disinfecting effect is obtained decreases from 21 hours at a temperature of 60 ° C to 1.7 hours at a temperature of 75 ° C.

Based on the results of experimental studies, a formula is obtained for determining the optimal duration of heat treatment until an almost complete disinfecting effect is obtained, provided that the sowing qualities of the seeds are preserved

where T _In - the temperature of the air blown through the layer, ° C;

W _H is the relative humidity of the seeds,%.

Therefore, in order to increase the processing efficiency, preserve the sowing quality of seeds and reduce energy consumption, it is advisable to optimize the duration of heat treatment when blowing a thin layer of seeds, to ensure their almost complete disinfection from anthracnose, while maintaining high sowing qualities.

There is a problem of creating such a technical solution.

The purpose of the invention is to increase the efficiency of processing, preservation of sowing qualities of seeds.

This goal is achieved by the fact that in the method of thermal disinfection of lupine seeds from the anthracnose pathogen, which includes heating the seeds to a predetermined temperature with convective heat supply in a stream of a heat carrier heated to a given temperature with a moisture content of 79-84%, blown through the seed layer, followed by keeping them when the temperature is reached for a certain period of time, the duration of the thermal effect on the seed layer with a thickness not exceeding 0.10-0.15 m is determined by the following dependence:

where T _B is the temperature of the coolant blown through the layer of seeds, ° C;

W _c - initial relative humidity of seeds,%.

The temperature of the coolant is selected in the range of 60 ... 75 ° C.

The proposed method is carried out on a known installation, including a chamber with a recirculation circuit, having a heater and a fan. Moreover, the recirculation circuit is equipped with a humidifier installed on the suction line of the circuit after the heater directly at the suction window of the fan.

The claimed method of disinfecting lupine seeds from the anthracnose pathogen satisfies the “substantial differences” criterion of protection, since the goal of increasing the efficiency of processing and preserving the sowing quality of seeds can be achieved only with a combination of signs: the duration of the heat exposure until an almost complete disinfecting effect should be at a level determined by according to the following relationship:

.

.

Moreover, the heating of seeds to a predetermined temperature is carried out in a thin layer not exceeding 0.10-0.15 m.

The implementation of the method in violation of at least one of these signs of the totality does not lead to the achievement of the goal. Thus, an increase in the duration of heat treatment to a value greater than that obtained by the ratio can lead to a decrease in the sowing quality of seeds, although an almost complete disinfecting effect (residual infection of the seeds at the level of 0.001%) will be achieved. A decrease in the duration of heat treatment compared with the value obtained by the ratio does not give the expected disinfecting effect.

An example of a specific implementation of the claimed method of heat treatment of lupine seeds at a coolant temperature of 65, 70 and 75 ° C, an initial seed moisture close to a conditional one, a purge layer thickness of 0.10-0.15 m and an initial seed infection with anthracnose 34% are shown in table 1.

From the table it follows that the claimed method allows to ensure almost complete disinfection of seeds from anthracnose in a thin layer, not exceeding 0.10-0.15 m, with the actual duration of heat exposure close to the calculated one. The sowing quality of the seeds at the same time remains almost at the initial level.

Table 1 The effect of thermal disinfection of seeds on their anthracnose infection and sowing qualities Heat carrier temperature, ° С Infection of seeds,% Duration of heat treatment, hour Seed germination,% source residual estimated by ratio actual before heat treatment after heat treatment 65 34.0 No more than 0.001 5.01 5.0 90.0 91.3 70 34.0 No more than 0.001 2.11 2.5 90.0 92.4 75 34.0 No more than 0.001 0.84 1.0 90.0 92.4

Field experiments in 2002 showed high efficiency of the method. In the areas where the sowing was carried out by seeds infected with anthracnose to a level of 14% and thermally processed using the inventive method at a temperature of 70 ° C for up to 2.5 hours, no anthracnose plants were found on the eve of flowering. In the control plot, where the sowing was carried out with the same seeds, but untreated thermally by the proposed method, the plant infection rate with anthracnose at that moment reached 18.7%.

In the experimental plots in 2003, where the sowing was carried out by seeds infected with anthracnose at an initial seed moisture of 10 ... 11%, followed by their thermal treatment by the claimed method at a temperature of 75 ° C for 1.6 hours, no infected plants were found in the stalk phase. In plots without heat treatment, the percentage of infected plants was 23.1%.

In the budding phase, a slight increase in infected plants was noted both in control plots and in experimental plots, 25.7 and 0.7%, respectively. In the flowering phase, plant infection with anthracnose in control plots without heat treatment increased to 84.2%. At the same time, in experimental plots with heat treatment did not exceed 12.4%.

As a result, if the seed yield in the control plots was 1.5 c / ha, in the experimental plots it reached 10.5 c / ha.

Figure 1 shows the results of thermal disinfection of lupine seeds in a thin layer with a thickness of not more than 0.10 ... 0.15 m with different relative humidity of the seeds and a coolant temperature of 65 ° C.

Figure 2 - the results of thermal disinfection of seeds at different temperatures and initial seed moisture of 10-12%.

Figure 3 shows a diagram of a device for implementing the method.

A device for implementing the method includes a sealed chamber 1 with a recirculation circuit 2 having a fan 3, an air heater 4, a humidifier of heated air 5.

The heated air humidifier 5 is connected by a steam line 6 through an electromagnetic valve 7 to the suction line of the recirculation loop 8. The chamber 1 is equipped with a loading 9 and unloading 10 hatches. A grill is provided inside the chamber 11. The temperature and humidity of the coolant blown through the seed layer is set and automatically maintained at a predetermined level using the temperature controller 12 and humidity controller 13. A psychrometer 14 is provided for visual monitoring of the temperature and humidity of the coolant.

The method is implemented in the operation of the device as follows. Seeds with a moisture content not exceeding 14% are loaded through the hatch 9 of chamber 1.

After starting fan 3, heater 4 and humidifier 5 are automatically turned on. When the temperature of the coolant is brought to the required value (60-75 ° C) using thermostat 13, heater 4 is automatically turned off. At the same time, using the electromagnetic valve 7, the steam supply from the humidifier 5 is turned on via the steam line 6 into the suction line of the recirculation circuit 8, where it is captured by the fan blades 3, mixed with a heated coolant, fed into the chamber 1 and then blown through formed on eshetke seed layer 11 a thickness of not more than 0.10 ... 0.15 m, warming them to a predetermined temperature.

After bringing the coolant humidity to a predetermined value using the controller 13, the humidifier 5 is automatically turned off, reducing or completely stopping the supply of steam to the suction line of the recirculation circuit 8.

Automatic inclusion of the heater 4 and humidifier 5 occurs when the temperature and humidity of the coolant in chamber 1 are lower than the specified values.

The spent coolant leaving the seed layer is fed back to the suction line 8 of the recirculation loop 2 for reuse.

Upon completion of the heat treatment process after a period of time τ _opt , determined by the ratio:

the fan shuts off. The steam supply from the humidifier also stops. The treated seeds are unloaded through the hatch 10.

Thus, the claimed method of disinfecting lupine seeds from a seed infection of anthracnose helps to increase the efficiency of the treatment, while maintaining the sowing qualities of the seeds.

Optimization of the duration of seed disinfection to obtain an almost complete disinfecting effect also reduces energy costs.

LITERATURE

1. Savchenko L.F. Laboratory method for thermal disinfection of lupine seeds from anthracnose pathogen. // All-Russian Research Institute of Phytopathology. Big Vyazma, 1997 (analogue).

2. WO 97/38737, 10.23.1997, (prototype).

Claims (2)

1. The method of thermal disinfection of lupine seeds from the anthracnose pathogen, comprising heating the seeds to a predetermined temperature with convective heat supply in a stream of a heat carrier heated to a given temperature with a moisture content of 79 ... 84%, blown through the seed layer, followed by keeping them at the reached temperature for a certain period of time, characterized in that the duration of the thermal effect on the seed layer with a thickness not exceeding 0.10-0.15 m, is determined by the following relationship: [(341 + 1.74Wc) / (38 + 0.62Wc)] - 0.1TB τopt = 0.016 · (TB-50) · 10, h, where TB is the temperature of the coolant blown through the seed layer, ° C; Wc is the initial relative humidity of the seeds. 2. The method according to claim 1, characterized in that the temperature of the coolant is selected in the range of 60-75 ° C.

Images