JP5948054B2 - Horticultural facilities - Google Patents

Description

  The present invention relates to a horticultural facility using a gas engine.

In a horticultural facility such as a vinyl house, temperature management inside the vinyl house is performed by a heat pump device using a gas engine. In such horticultural facilities, in order to improve the production efficiency of cultivated crops, heavy oil is burned in a vinyl house to enrich the CO ₂ gas necessary for photosynthesis. Yes.

  However, if a heat pump device using a gas engine is used and heavy oil is burned, the energy efficiency is deteriorated.

Therefore, conventionally, it has been considered to use exhaust gas of a gas engine for enrichment of CO ₂ gas (see, for example, Patent Document 1).

At this time, the air-fuel ratio control of the gas engine is performed within a predetermined λ window where the fuel is slightly thicker than the ideal air-fuel ratio so that toxic exhaust gas components such as CO, NO _x , and hydrocarbons in the exhaust gas are reduced. The exhaust gas was purified with a catalyst, and the CO ₂ gas was enriched.

Japanese National Patent Publication No. 11-500203

However, in the conventional horticultural facility, when the catalyst is deteriorated, the toxic exhaust gas component is not removed, and the exhaust gas having such a toxic exhaust gas component flows into the horticultural facility. Become. As a result, CO and NO _X endanger the workers who work in the horticultural facility, and the hydrocarbons end up with the crops grown in the horticultural facility.

  The present invention provides a gardening facility capable of detecting the deterioration of a catalyst and ensuring the safety of workers in the gardening facility.

The horticultural facility of the present invention for solving the above-mentioned problem is a horticultural facility configured to adjust the temperature in the facility main body by a heat pump driven by the engine, and the exhaust gas path of the engine includes the exhaust gas. A sensor for measuring the temperature of the upstream side and the downstream side of the catalyst provided in the path is provided, and a switching valve for discharging exhaust gas in the facility main body or outdoors is provided on the downstream side of the catalyst, and the sensor When the temperature difference between the upstream and downstream sides of the catalyst measured by the above is greater than or equal to a predetermined value, exhaust gas is introduced into the facility body. a control unit for controlling the switching valve to exhaust gas, the control unit and the engine load calculated from the load of the inlet and outlet of the compressor to be operated by an engine, the engine Based on the control map of the amount of toxic exhaust gas components in the exhaust gas created from the relationship with the rotation number, when the toxic exhaust gas components have a low concentration, the exhaust gas is introduced into the facility main body, In this case, the switching valve is controlled so as to discharge exhaust gas outdoors regardless of the control of the switching valve based on the temperature difference .

As described above, according to the present invention, the deterioration of the catalyst can be detected by monitoring the purification of toxic gas components such as CO, NO _x , and hydrocarbons in the exhaust gas. It is possible to ensure safety and prevent the crops from withering.

It is a block diagram which shows the outline of the whole gardening facility which concerns on this invention. It is the schematic which shows the structure of the catalyst part provided in the exhaust-gas path | route of the gas engine of the gardening facility which concerns on this invention. It is a graph which shows the relationship between the temperature difference of the upstream and downstream of a catalyst, and an average effective pressure.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a horticultural facility 1 according to the present invention, and FIG. 2 shows a configuration of a catalyst 33 portion provided in an exhaust gas path 32 of a gas engine 31 that drives a heat pump 3 of the horticultural facility 1.

  The horticultural facility 1 is a horticultural facility 1 configured to adjust the temperature in the facility body 2 by a heat pump 3 driven by a gas engine 31, and a catalyst provided in an exhaust gas path 32 of the gas engine 31. Temperature sensors 34a and 34b are provided on the upstream side and the downstream side of 33, and further on the downstream side, a switching valve 35 for exhausting exhaust gas into the facility body 2 or outdoors is provided, and the temperature sensors 34a and 34b are provided. When the temperature difference D between the upstream side and the downstream side of the catalyst 33 measured by the above is greater than or equal to a predetermined value, exhaust gas is introduced into the facility body 2, and when the temperature difference D is less than the predetermined value, an alarm is issued. It has the control part 10 which controls the said switching valve 35 so that exhaust gas may be discharged | emitted outdoors.

  The facility body 2 is configured to surround a cultivated land 21 where crops and plants can be cultivated to form a closed space in which the internal environment can be controlled. The cultivated land 21 may be a fixed medium such as soil or a solution medium such as a hydroponic medium. In addition, in the facility main body 2, a part or all of the roof portion 22 or the wall portion 23 is formed of a translucent material so that sunlight can be collected inside. Specific examples of the facility main body 2 include a vinyl house or a glass house.

  In addition, the facility body 2 is provided with an openable and closable skylight 22 a that can be ventilated on the roof portion 22. The skylight 22a may be provided on the wall portion 23. Further, instead of the skylight 22a, a ventilation fan or the like capable of forced ventilation may be provided.

  Immediately below the roof portion 22 of the facility main body 2 is provided a curtain 24 that shields light and prevents wind. By blocking the sunlight with this curtain 24, the amount of sunlight can be adjusted, or the curtain 24 can be expanded to a desired position, thereby adjusting the wind direction and speed of the wind taken from the skylight 22a when the skylight 22a is opened. .

  In addition, the facility main body 2 may be a case where artificial light cultivation is performed using LED light or the like without using sunlight. In this case, the roof part 22 and the wall part 23 may not be a translucent material as described above, and the curtain 24 may be omitted. Therefore, in the case of artificial light cultivation, the facility body 2 may be configured as a part of a house, a building, a factory, or an underground facility, or may be a building that is configured exclusively as a plant factory. Further, the scale of the facility main body 2 is not particularly limited, and may be a factory scale capable of mass production or a small scale at the level of a home garden.

  The heat pump 3 is configured to operate by driving a compressor (not shown) by the gas engine 31. The heat pump 3 is provided with an indoor unit 36 in the facility main body 2 so that the temperature in the facility main body 2 can be managed by cold air or hot air from the indoor unit 36.

  The gas engine 31 that is a drive source of the heat pump 3 may drive one compressor according to a load to operate one heat pump cycle, or a plurality or one according to the load. The compressor may be driven to switch over a plurality of or one heat pump cycle.

  A catalyst 33 is provided in the exhaust gas path 32 from the gas engine 31. Temperature sensors 34 a and 34 b are provided on the upstream side and the downstream side of the catalyst 33, respectively.

  The temperature sensors 34 a and 34 b measure the temperature difference D between the exhaust gas before and after passing through the catalyst 33 by measuring the temperature between the upstream side and the downstream side of the catalyst 33. This measurement result is sent to the control unit 10 to detect whether or not the temperature difference D is a predetermined value. The exhaust gas path 32 further downstream of the catalyst 33 branches into a path 32a that guides the exhaust gas to the outside and a path 32b that leads into the facility main body 2, and a switching valve 35 provided at this branch point. It is possible to switch between exhaust gas being exhausted outdoors or exhausting into the facility body 2.

In the catalyst 33, a toxic gas component in the exhaust gas is decomposed by an oxidation reaction or the like. That is, CO in the exhaust gas is decomposed into CO ₂ by an oxidation reaction, and the hydrocarbon is decomposed into water and CO ₂ . NO _X in the exhaust gas is decomposed into N ₂ by the reaction. At this time, since heat of reaction is generated, the temperature detected by the downstream temperature sensor 34 b after passing through the catalyst 33 is higher than the temperature detected by the upstream temperature sensor 34 a before flowing into the catalyst 33. Become. Therefore, as shown in FIG. 3, the relationship between the temperature difference D between the upstream side and the downstream side of the catalyst 33 measured by the temperature sensors 34a and 34b is as long as the catalyst 33 functions effectively. A constant temperature difference D is maintained with respect to the average effective pressure. However, when the function of the catalyst 33 is deteriorated, the toxic gas component in the exhaust gas is not decomposed by the oxidation reaction or the like and there is no reaction heat, so the temperature difference D becomes small. Therefore, when the temperature difference D is a predetermined value, the toxic gas component in the exhaust gas is processed at the catalyst 33 to have a low concentration. When the temperature difference D is less than the predetermined value, the catalyst 33 is deteriorated and is not processed to have a high concentration. Become. This temperature difference D changes according to the rotation speed of the gas engine 31, the load, the excess air ratio, and the ignition timing.

  The controller 10 receives information on the temperature difference D as shown in FIG. 3. When the temperature difference D is a predetermined value, the control unit 10 switches the switching valve 35 to supply the exhaust gas from the engine 31 to the facility main body. When the value is less than the predetermined value, the switching valve 35 is switched to control the exhaust gas from the engine 31 to be discharged outdoors. Further, when the temperature difference D is less than a predetermined value, the control unit 10 issues an alarm because the catalyst 33 deteriorates and cannot be used thereafter. This alarm may be due to the lighting of a lamp, may be due to the generation of an alarm sound, may be displayed on a control panel, or the heat pump 3 or the gas engine 31 It may be due to a stop. Further, a combination of a plurality of these alarms may be used.

The horticultural facility 1 configured in this way can take the exhaust gas treated with the catalyst 33 and enriched with CO ₂ into the facility main body 2 by switching the switching valve 35. Can promote the growth of crops and plants.

  Further, since the control unit 10 can notify the alarm that the catalyst 33 has deteriorated and the toxic gas component cannot be decomposed, the exhaust gas while ensuring the safety of workers working in the facility body 2. Can be taken into the facility main body 2.

In this embodiment, CO, hydrocarbons, but using the catalyst 33 corresponding to the NO _X, some such operating conditions of 31 of the fuel used and the engine, not a catalyst 33 corresponding to all of these Also good. For example, in the case of the engine 31 for lean operation, the generation of NO _X does not cause a problem, and therefore the catalyst 33 corresponding to CO and hydrocarbon can be used. Even in this case, CO, as well as hydrocarbon, the catalyst 33 that corresponds to the NO _X, it is possible to detect deterioration of the catalyst 33 to monitor the temperature.

Further, in this embodiment, CO with a catalyst 33, a hydrocarbon, and the NO _X have been made to remove by oxidation reaction or the like, instead of the catalyst 33 decomposes the CO and hydrocarbon A catalyst and a catalyst for decomposing NO _X are provided separately, and temperature sensors 34a and 34b are provided on the upstream side and the downstream side of these catalysts, respectively, so that deterioration of each catalyst can be distinguished separately from the temperature difference D. Good. In this case, untreated exhaust gas due to catalyst deterioration can be detected even under combustion conditions that cannot be handled by the catalyst 33. Further, the deterioration state of the catalyst can be confirmed in more detail.

However, NO _X in the exhaust gas cannot be decomposed using the catalyst 33 depending on the operating state. Therefore, in an operating situation in which NO _X in the exhaust gas cannot be decomposed, the switching valve 35 is switched to exhaust the exhaust gas outdoors regardless of the deterioration of the catalyst 33 described above. Whether NO _X can be decomposed or not is determined based on the relationship between the rotational speed of the engine 31 and the load, and the NO _X amount in the exhaust gas discharged from the engine 31 is previously input as a control map. A determination is made based on this control map. As the control map, is not limited to those based on the concentration of the NO _X in the exhaust gas, for example, the concentration of CO in the exhaust gas may be obtained by the reference, the exhaust gas It may be based on the concentration of the hydrocarbon therein. In the case of the control map based on the CO concentration, the operator can be protected from the danger of being exposed to high-concentration CO gas, and is similar to the control map based on the NO _X concentration shown in the present embodiment. In addition, the safety of the worker can be improved. Moreover, in the case of the control map based on the concentration of hydrocarbon, it is possible to prevent the crops and plants cultivated in the facility body 2 from being exposed to high concentration of hydrocarbon and withering.

Further, the control unit 10 may control the NO _X control map, the CO control map, and the hydrocarbon control map in combination.

  The horticultural facility according to the present invention is used for cultivation of various agricultural products and plants.

DESCRIPTION OF SYMBOLS 1 Horticultural facility 10 Control part 2 Facility body 3 Heat pump 31 Gas engine 32 Exhaust gas path 33 Catalyst 34a Temperature sensor 34b Temperature sensor 35 Switching valve

Claims (1)

A horticultural facility configured to adjust the temperature in the facility body by an engine-driven heat pump,
The exhaust gas path of the engine is provided with a sensor for measuring the temperature of the upstream side and the downstream side of the catalyst provided in the exhaust gas path. A switching valve is provided to discharge
When the temperature difference between the upstream side and the downstream side of the catalyst measured by the sensor is greater than or equal to a predetermined value, exhaust gas is introduced into the facility body. A control unit for controlling the switching valve so as to exhaust the exhaust gas,
The control unit is based on a control map for the amount of toxic exhaust gas components in the exhaust gas created from the relationship between the engine load calculated from the inlet and outlet loads of the compressor operated by the engine and the engine speed. In addition, when the concentration of toxic exhaust gas components is low, exhaust gas is introduced into the facility body, and when the concentration is high, exhaust gas is discharged outdoors regardless of the control of the switching valve based on the temperature difference. A gardening facility characterized by controlling the switching valve.

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