CN210154208U - Intelligent air energy drying system - Google Patents
Intelligent air energy drying system Download PDFInfo
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- CN210154208U CN210154208U CN201920331703.0U CN201920331703U CN210154208U CN 210154208 U CN210154208 U CN 210154208U CN 201920331703 U CN201920331703 U CN 201920331703U CN 210154208 U CN210154208 U CN 210154208U
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Abstract
The utility model discloses an intelligent air energy drying system, which comprises a drying room, a control system, a steam generator, at least one steam pipeline, at least one temperature sensor, at least one humidity sensor and at least two groups of air energy heating systems, wherein the steam pipeline is arranged in the drying room and used for spraying steam into the drying room, and the steam pipeline is communicated with the steam generator; the air energy heating system comprises an evaporator, a compressor, a condenser, a throttling device and a circulating fan; the circulating fan is arranged in the drying room, the position of the circulating fan corresponds to that of the condenser, and the circulating fan is used for forming circulating air flow in the drying room. The utility model has small energy consumption, sensitive control of parameters such as heating power and temperature control, and convenient maintenance; the forward circulating air flow and the reverse circulating air flow can be formed alternately; the temperature and humidity in the drying room can be monitored in real time; the humidifying device can humidify the interior of the drying room, reduce the moisture in the interior and on the surface of the material, and prevent the material from deforming and cracking.
Description
Technical Field
The utility model relates to a drying equipment technical field, in particular to intelligence air can drying system.
Background
Drying generally refers to the process of heating heat above a wet material and removing the moisture from the material side by side to obtain a solid product with a lower moisture content. In thermal drying, the following two processes occur sequentially, with the drying rate being controlled sequentially. Process 1, the transfer of energy from the surrounding environment to the surface of the material, causing the surface moisture of the material to evaporate and the liquid to be discharged from the surface of the material in vapour form, the rate of which depends on the conditions of temperature, air humidity, air flow rate, heat transfer area and pressure of the material, also known as the constant drop drying process. And (2) a process: the internal moisture is transferred to the surface of the material, and surface evaporation occurs; the migration of moisture within the material is a function of the material properties, temperature and humidity, and this process is also known as the falling rate drying process.
State of moisture: under the condition of certain temperature and water content, the surface of the material has certain water vapor pressure P1, and the size of the material is different with the temperature and the water content. The material has higher water content, the water vapor pressure on the surface of the material is higher, if the water vapor pressure on the surface of the material P1 is higher than the water vapor pressure in the air P2, namely P1 is more than P2, the material is dehydrated and dried, and the process is called analytic drying; if P1 < P2, the material will absorb water vapour from the surrounding air, called adsorption. When the air pressure of the moisture content of the surface of the material is equal to the water vapor pressure of the surrounding air, namely P1= P2, the moisture content in the material is not changed any more, a dynamic equilibrium state appears, the moisture content is called equilibrium moisture, the moisture content of the material exceeds the equilibrium to be free moisture, and the moisture can be removed by a drying method.
Based on the above drying principle, various drying apparatuses have been developed and manufactured. In the prior art, the drying equipment mainly comprises coal-fired boiler drying equipment, oil-fired boiler drying equipment and electric heater drying equipment. However, these drying apparatuses have the following disadvantages: firstly, the heat efficiency is low, the drying cost is high, the drying equipment of a coal-fired boiler can only reach 42 percent, the drying equipment of an oil-fired boiler can only reach 75 percent, and the drying equipment of a heater in the year can only reach 95 percent; secondly, potential safety hazards such as explosion, fire and the like exist in the coal-fired boiler drying equipment and the oil-fired boiler drying equipment, and potential safety hazards such as electric leakage exist in the electric heater drying equipment; and thirdly, harmful gases such as sulfur oxide, carbon monoxide and the like and carbon dioxide greenhouse gases can be generated by coal-fired boiler drying equipment and oil-fired boiler drying equipment, so that the environment is seriously polluted, and the maintenance cost is high.
In view of this, air energy drying apparatuses have been developed and manufactured. The air energy drying equipment is also called heat pump drying equipment, the average heat efficiency can reach more than 300%, the drying cost is low, the air energy drying equipment is safe and reliable, does not pollute the environment, the maintenance cost is low, and the air energy drying equipment gradually has the uniform trend of replacing the traditional drying equipment. Chinese patent application 201810109427.3 discloses a closed loop heat pump drying-machine, including drying-machine and the stoving room of being connected with the drying-machine, the drying-machine include the shell and the air heating device that sets up in the shell, the top and the below of shell set up air outlet one and air intake one respectively, stoving room top be provided with the air intake two that is connected with air outlet one, the below in stoving room be provided with the air outlet two that is connected with air intake one, air heating device include that air intake one and air outlet set gradually between one the evaporator of disconnect-type heat pipe regenerator, the evaporimeter of heat pump, the condenser of disconnect-type heat pipe regenerator and the condenser of heat pump.
However, the closed loop heat pump dryer of the above-mentioned patent application 201810109427.3 has the following disadvantages: one heat pump heating system is only provided, a single heat pump is large in size, large in overall energy consumption, and not sensitive in parameter control in aspects of heating power, temperature control and the like, so that the heat pump heating system is inconvenient to overhaul and increase or decrease; secondly, the air flow always flows towards one direction in the drying room, and the materials cannot be dried from a plurality of angles; thirdly, a temperature sensor and a humidity sensor are not arranged, so that the temperature and the humidity in the drying room cannot be monitored in real time; the steam generator is not arranged, and the humidification in the drying room can not be realized, so that the difference between the moisture humidity inside the material and the moisture humidity on the surface is too large, the cracking problem of the material is easy to occur, especially wood materials are easy to be few and crack when being continuously heated and dried, and the great loss is caused.
SUMMERY OF THE UTILITY MODEL
The utility model aims to solve the technical problem of providing an intelligent air energy drying system aiming at the defects of the prior art, wherein the drying system adopts a plurality of sets of air energy drying systems, a single heat pump has small volume, small overall energy consumption, sensitive parameter control in aspects of heating power, temperature control and the like, is convenient to overhaul, and is convenient to increase or reduce the air energy drying system; in a drying room of the drying system, forward circulating air flow and reverse circulating air flow can be alternately formed, and materials are dried from multiple angles; the drying system is provided with a temperature sensor and a humidity sensor, and can monitor the temperature and the humidity in the drying room in real time; the drying system is provided with the steam generator, and can humidify the inside of the drying room, reduce the moisture and humidity inside and on the surface of the material and prevent the material from deforming and cracking.
In order to solve the technical problem, the utility model discloses technical scheme is: an intelligent air energy drying system comprises a drying room, a control system, a steam generator, at least one steam pipeline, at least one temperature sensor, at least one humidity sensor and at least two groups of air energy heating systems, wherein the control system is electrically connected with the steam generator, the temperature sensor, the humidity sensor and the air energy heating systems respectively; the steam pipeline is arranged in the drying room and used for spraying steam into the drying room, and the steam pipeline is communicated with the steam generator; the air energy heating system comprises an evaporator, a compressor, a condenser, a throttling device and a circulating fan, wherein the evaporator is installed outside the drying room, the condenser is installed inside the drying room, a working medium conveying loop is formed among the evaporator, the compressor, the condenser and the throttling device, the evaporator absorbs heat in outside air, and the heat is released into the drying room by the condenser after the compressor works; the circulating fan is arranged in the drying room, the position of the circulating fan corresponds to that of the condenser, and the circulating fan is used for forming circulating air flow in the drying room; temperature-sensing ware and humidity inductor install respectively in the stoving room, temperature-sensing ware is used for detecting the temperature in the stoving room to feed back control system with temperature information, humidity-sensing ware is used for detecting the humidity in the stoving room, and feeds back control system with humidity information.
Preferably, the drying room comprises a left side plate, a right side plate, a rear side plate, a top plate and a front door; a partition board is arranged at the upper end in the drying room, the left end of the partition board is connected with the left side board, the right end of the partition board is connected with the right side board, and the rear end of the partition board is connected with the rear side board; the distance between the partition board and the top board is 0.1-2.0 m, so that an air duct is formed between the partition board and the top board; the distance between the front end of the partition board and the front door is 0.1-2.0 m, so that a front ventilation opening is formed between the partition board and the front door; the circulating fan is arranged at the rear end of the partition plate, the condenser is provided with a radiator, the radiator is arranged above the circulating fan, the circulating fan can rotate forwards and reversely, when the circulating fan rotates forwards, heat released by the condenser through the radiator is blown downwards into the drying room under the action of the circulating fan, and then upwards enters the air duct from the front air vent of the partition plate to form forward circulating air flow; when the circulating fan rotates reversely, the heat released by the condenser through the radiator is blown into the air duct above the partition plate under the action of the circulating fan, then enters the drying room from the front air vent of the partition plate downwards, and then enters the circulating fan from the drying room upwards to form reverse circulating air flow.
Preferably, the drying room comprises a left side plate, a right side plate, a rear side plate, a top plate and a front door; a partition board is arranged at the upper end in the drying room, the left end of the partition board is connected with the left side board, and the right end of the partition board is connected with the right side board; the distance between the partition board and the top board is 0.1-2.0 m, so that an air duct is formed between the partition board and the top board; the distance between the front end of the partition board and the front door is 0.1-2.0 m, so that a front ventilation opening is formed between the partition board and the front door; the distance between the rear end of the partition board and the rear side board is 0.1-2.0 m, so that a rear ventilation opening is formed between the partition board and the rear door; the circulating fan is arranged in the air duct above the partition plate, the condenser is provided with two radiators which are respectively arranged in the front and the rear directions of the circulating fan, the circulating fan can rotate forwards and reversely, and when the circulating fan rotates forwards, heat released by the condenser through the radiators is blown downwards into the drying room from the rear vent of the partition plate under the action of the circulating fan and then upwards enters the air duct from the front vent of the partition plate to form forward circulating air flow; when the circulating fan rotates reversely, the heat released by the condenser through the radiator is blown downwards into the drying room from the front vent of the partition plate under the action of the circulating fan, and then upwards enters the air channel from the rear vent of the partition plate to form reverse circulating air flow.
Preferably, a control room is arranged on one side of the drying room, and the control system is installed in the control room; the control system comprises a control mainboard and a touch panel, wherein the control mainboard is electrically connected with the touch panel through a data line; the control main board is provided with an MCU (microprogrammed control unit), and the MCU is electrically connected with a plurality of protection switches, a humidity sensor and a rectification filter switch circuit; the touch panel comprises a display screen and a touch input device, wherein the touch input device comprises an on-off key, a + key, a-key, a function key and a timing key.
Preferably, the lower end of the front side of the drying room is provided with a slide rail, the lower end of the front door is in sliding fit with the slide rail, so that the front door can move along the slide rail to open or close the drying room, and a sealing strip is arranged at the front side frame of the drying room and used for sealing the front door and the inside of the drying room; and heat insulation cotton is respectively arranged in the left side plate, the right side plate, the rear side plate, the top plate and the front door.
The utility model has the advantages that: firstly, the average heat efficiency of the intelligent air energy drying system can reach more than 330%, the drying cost is low, the system is safe and reliable, the environment is not polluted, and the maintenance cost is low; secondly, the utility model adopts multiple sets of air energy drying systems, the single heat pump has small volume, small overall energy consumption, sensitive parameter control in aspects of heating power and temperature control, convenient maintenance and convenient increase or decrease of the air energy drying systems, for example, if the utility model is provided with 8 sets of air energy drying systems, when the demand of instant heating power is small, the control device only needs to control the operation of less air energy drying systems (for example, 3 sets) or control the low-power operation of all air energy drying systems; when the demand of the instant heating power is larger, the control device controls more air energy drying systems (for example, 8 groups) to operate or controls all the air energy drying systems to operate at high power; thirdly, the forward circulating air flow and the reverse circulating air flow can be formed alternately in the drying room of the drying system, the materials can be dried from a plurality of angles, and the drying is sufficient and the effect is good; fourthly, the drying system of the utility model is provided with a plurality of temperature sensors and a plurality of humidity sensors, which can monitor the temperature and humidity in the drying room in real time from each position of the drying room; fifthly, the utility model discloses drying system is provided with steam generator, can reduce the inside and surperficial moisture humidity of material to the interior humidification of stoving room, makes the inside moisture of material fully appear, prevents that material surface drying and inside humidity is high for the material (for example this village) indeformable, do not ftracture.
Drawings
Fig. 1 is a functional block diagram of the overall structure of the present invention.
Fig. 2 is the external structure schematic diagram of the utility model after the front door is opened.
Fig. 3 is the external structure schematic diagram of the utility model after the front door is closed.
Fig. 4 is a schematic view of an internal cross-sectional structure according to a preferred embodiment of the present invention.
Fig. 5 is a second schematic diagram of the internal cross-sectional structure of a preferred embodiment of the present invention.
Fig. 6 is a schematic view of an internal cross-sectional structure of another preferred embodiment of the present invention.
Fig. 7 is a second schematic diagram of the internal cross-sectional structure of another preferred embodiment of the present invention.
Fig. 8 is a circuit configuration diagram of the control main board.
Fig. 9 is a circuit structure diagram of the touch panel.
Detailed Description
The structure and operation of the present invention will be described in detail with reference to the accompanying drawings.
As shown in fig. 1-9, the utility model relates to an intelligence air can drying system for dry material 100, this material 100 is article such as food, timber. The utility model discloses intelligent air can drying system includes drying room 1, control system 2, steam generator 3, at least one steam conduit 4, at least one temperature-sensing ware 5, at least one humidity inductor 6 and at least two sets of air can heat system 7, control system 2 respectively with steam generator 3, temperature-sensing ware 5, humidity inductor 6 and air can heat system 7 electric connection; the steam pipeline 4 is arranged in the drying room 1 and used for spraying steam into the drying room 1, and the steam pipeline 4 is communicated with the steam generator 3; the air energy heating system 7 comprises an evaporator 71, a compressor 72, a condenser 73, a throttling device 74 and a circulating fan 75, wherein the evaporator 41 is installed outside the drying room 1, the condenser 73 is installed inside the drying room 1, a working medium conveying loop is formed among the evaporator 71, the compressor 72, the condenser 73 and the throttling device 74, the evaporator 71 absorbs heat in outside air, and the heat is released into the drying room 1 by the condenser 73 after the compressor 72 applies work; the circulation fan 75 is installed in the drying room 1, the position of the circulation fan 75 corresponds to the position of the condenser 73, and the circulation fan 75 is used for forming a circulation air flow in the drying room 1; temperature-sensing ware 5 and humidity inductor 6 install respectively in stoving room 1, temperature-sensing ware 5 is used for detecting the temperature in the stoving room 1 to feed back control system 2 with temperature information, humidity-sensing ware 6 is used for detecting the humidity in the stoving room 1, and feeds back control system 2 with humidity information.
As shown in fig. 2 to 5, as a preferred embodiment of the present invention, the drying room 1 includes a left side plate 11, a right side plate 12, a rear side plate 13, a top plate 14, and a front door 15; a partition plate 16 is arranged at the upper end in the drying room 1, the left end of the partition plate 16 is connected with the left side plate 11, the right end of the partition plate 16 is connected with the right side plate 12, and the rear end of the partition plate 16 is connected with the rear side plate 13; the distance between the partition plate 16 and the top plate 14 is 0.1-2.0 m, preferably 0.6-1.2 m, so that an air duct is formed between the partition plate 16 and the top plate 14; the distance between the front end of the clapboard 16 and the front door 15 is 0.1-2.0 m, preferably 0.6-1.2 m, so that a front ventilation opening is formed between the clapboard 16 and the front door; the circulation fan 75 is installed at the rear end of the partition 16, the condenser is provided with a radiator 76, the radiator 76 is installed above the circulation fan 75, the circulation fan 75 can rotate forward and backward, when the circulation fan 75 rotates forward, the heat released by the condenser through the radiator 76 is blown downwards into the drying room 1 under the action of the circulation fan 75, and then enters the air duct upwards from the front air vent of the partition 16 to form forward circulation air flow; when the circulation fan 75 rotates reversely, the heat released from the condenser via the radiator 76 is blown into the air duct above the partition plate 16 by the circulation fan 75, and then enters the drying room 1 from the front air vent of the partition plate 16 downward, and then enters the circulation fan 75 from the drying room 1 upward, thereby forming a reverse circulation air flow. Further, install a plurality of on the roof 14 of stoving room 1 and arrange wet machine 77, arrange the quantity of wet machine 77 and circulating fan 75's quantity phase-match, arrange wet machine 77 and set up in circulating fan 75's top, it is provided with the hydrofuge door to arrange wet machine 77.
As shown in fig. 2, 3, 6 and 7, as another preferred embodiment of the present invention, the drying room 1 includes a left side plate 11, a right side plate 12, a rear side plate 13, a top plate 14 and a front door 15; a partition plate 16 is arranged at the upper end in the drying room 1, the left end of the partition plate 16 is connected with the left side plate 11, and the right end of the partition plate 16 is connected with the right side plate 12; the distance between the partition plate 16 and the top plate 14 is 0.1-2.0 m, preferably 0.6-1.2 m, so that an air duct is formed between the partition plate 16 and the top plate 14; the distance between the front end of the clapboard 16 and the front door 15 is 0.1-2.0 m, preferably 0.6-1.2 m, so that a front ventilation opening is formed between the clapboard 16 and the front door 15; the distance between the rear end of the partition plate 16 and the rear side plate 13 is 0.1-2.0 meters, preferably 0.6-1.2 meters, so that a rear ventilation opening is formed between the partition plate 16 and the rear door 13; the circulating fan 75 is arranged in the air duct above the partition plate 16, the condenser is provided with two radiators 76 which are respectively arranged in the front and the rear of the circulating fan 75, the circulating fan 75 can rotate forwards and reversely, when the circulating fan 75 rotates forwards, the heat released by the condenser through the radiators 76 is blown downwards into the drying room 1 from the rear vent of the partition plate 16 under the action of the circulating fan 75, and then upwards enters the air duct from the front vent of the partition plate 16 to form forward circulating air flow; when the circulation fan 75 rotates reversely, the heat released from the condenser via the radiator 76 is blown downward into the drying room from the front vent of the partition 16 under the action of the circulation fan 75, and then enters the air duct from the rear vent of the partition 16 upward to form a reverse circulation air flow. Further, a plurality of dehumidifying machines 77 are installed on the top plate 14 of the drying room 1, the dehumidifying machines 77 are disposed above the circulating fan 75, and the dehumidifying machines 77 are provided with a dehumidifying door.
As shown in fig. 2-9, a control room 8 is provided at one side of the drying room 1, and the control system 2 is installed in the control room 8; the control system 2 comprises a control main board (refer to fig. 8) and a touch panel (refer to fig. 9), wherein the control main board is electrically connected with the touch panel through a data line; the control main board is provided with an MCU (microprogrammed control unit), and the MCU is electrically connected with a plurality of protection switches, a humidity sensor and a rectification filter switch circuit; the touch panel comprises a display screen and a touch input device, wherein the touch input device comprises an on-off key, a + key, a-key, a function key and a timing key.
As shown in fig. 2, the steam pipe 4 is installed inside the left side plate 11, the right side plate 12 and the rear side plate 13, and a plurality of steam injection holes are arranged on the steam pipe 4.
As shown in fig. 2, a slide rail 9 is arranged at the lower end of the front side of the drying room 1, the lower end of the front door 15 is in sliding fit with the slide rail 9, so that the front door 15 can move along the slide rail 9 to open or close the drying room 1, and a sealing strip 17 is arranged at the front side frame of the drying room 1 for sealing the front door 15 and the drying room 1; and heat insulation cotton is respectively arranged in the left side plate 11, the right side plate 12, the rear side plate 13, the top plate 14 and the front door 15.
The drying method of the intelligent air energy drying system comprises the following steps:
s1, starting an intelligent air energy drying system, and controlling a steam generator, a temperature sensor, a humidity sensor and an air energy heating system to start working through a control system;
s2, heating and warming the drying room by the air energy heating system, and raising the temperature in the drying room to a first set drying temperature; the steam machine is used for spraying steam for humidifying in the drying room, and the humidity in the drying room is improved to a first set humidity; the temperature rise time and the steam spraying time are set according to the materials to be dried; the heating mode adopts a step-type heating or continuous heating mode;
s3, the air energy heating system and the steam engine continue to work, the control system controls the drying room to keep a constant temperature and humidity state, the temperature is a second set drying temperature, the humidity is a second set humidity, and the constant temperature and humidity time is set according to the materials to be dried;
s4, the air energy heating system continues to work, the control system controls the drying room to keep a constant temperature state, the temperature is a third set drying temperature, the steam engine is closed, the dehumidifying window is opened, dehumidifying treatment is gradually carried out on the drying room, and the constant temperature dehumidifying time is set according to the materials to be dried;
s5, the air energy heating system continues to work, the control system controls the drying room to dry the materials to be dried at a constant temperature under low humidity, the temperature is a fourth set drying temperature, and the constant temperature drying time is set according to the materials to be dried;
s6, the control system controls the drying room to gradually cool under low humidity, the cooling time is set according to the materials to be dried, and after cooling, the drying step of the materials is completed;
in the above steps S2-S6, the control system controls the circulation fan to change the forward rotation direction and the reverse rotation direction at intervals, so that the forward circulation air flow and the reverse circulation air flow are alternately formed in the drying room; the temperature sensor feeds real-time temperature information back to the control system, and the humidity sensor feeds real-time humidity information back to the control system.
The above, only the utility model discloses preferred embodiment, all be according to the utility model discloses a technical scheme does any slight modification, the equivalent change and the modification to above embodiment, all belong to the utility model discloses technical scheme's within range.
Claims (8)
1. Intelligence air can drying system, its characterized in that: the drying room comprises a drying room, a control system, a steam generator, at least one steam pipeline, at least one temperature sensor, at least one humidity sensor and at least two groups of air energy heating systems, wherein the control system is electrically connected with the steam generator, the temperature sensor, the humidity sensor and the air energy heating systems respectively; the steam pipeline is arranged in the drying room and used for spraying steam into the drying room, and the steam pipeline is communicated with the steam generator; the air energy heating system comprises an evaporator, a compressor, a condenser, a throttling device and a circulating fan, wherein the evaporator is installed outside the drying room, the condenser is installed inside the drying room, a working medium conveying loop is formed among the evaporator, the compressor, the condenser and the throttling device, the evaporator absorbs heat in outside air, and the heat is released into the drying room by the condenser after the compressor works; the circulating fan is arranged in the drying room, the position of the circulating fan corresponds to that of the condenser, and the circulating fan is used for forming circulating air flow in the drying room; temperature-sensing ware and humidity inductor install respectively in the stoving room, temperature-sensing ware is used for detecting the temperature in the stoving room to feed back control system with temperature information, humidity-sensing ware is used for detecting the humidity in the stoving room, and feeds back control system with humidity information.
2. The intelligent air energy drying system of claim 1, wherein: the drying room comprises a left side plate, a right side plate, a rear side plate, a top plate and a front door; a partition board is arranged at the upper end in the drying room, the left end of the partition board is connected with the left side board, the right end of the partition board is connected with the right side board, and the rear end of the partition board is connected with the rear side board; the distance between the partition board and the top board is 0.1-2.0 m, so that an air duct is formed between the partition board and the top board; the distance between the front end of the partition board and the front door is 0.1-2.0 m, so that a front ventilation opening is formed between the partition board and the front door; the circulating fan is arranged at the rear end of the partition plate, the condenser is provided with a radiator, the radiator is arranged above the circulating fan, the circulating fan can rotate forwards and reversely, when the circulating fan rotates forwards, heat released by the condenser through the radiator is blown downwards into the drying room under the action of the circulating fan, and then upwards enters the air duct from the front air vent of the partition plate to form forward circulating air flow; when the circulating fan rotates reversely, the heat released by the condenser through the radiator is blown into the air duct above the partition plate under the action of the circulating fan, then enters the drying room from the front air vent of the partition plate downwards, and then enters the circulating fan from the drying room upwards to form reverse circulating air flow.
3. The intelligent air energy drying system of claim 2, wherein: install a plurality of hydrofuge machine on the roof in stoving room, the quantity of hydrofuge machine and circulating fan's quantity phase-match, the hydrofuge machine sets up in circulating fan's top, the hydrofuge machine is provided with the hydrofuge door.
4. The intelligent air energy drying system of claim 1, wherein: the drying room comprises a left side plate, a right side plate, a rear side plate, a top plate and a front door; a partition board is arranged at the upper end in the drying room, the left end of the partition board is connected with the left side board, and the right end of the partition board is connected with the right side board; the distance between the partition board and the top board is 0.1-2.0 m, so that an air duct is formed between the partition board and the top board; the distance between the front end of the partition board and the front door is 0.1-2.0 m, so that a front ventilation opening is formed between the partition board and the front door; the distance between the rear end of the partition board and the rear side board is 0.1-2.0 m, so that a rear ventilation opening is formed between the partition board and the rear door; the circulating fan is arranged in the air duct above the partition plate, the condenser is provided with two radiators which are respectively arranged in the front and the rear directions of the circulating fan, the circulating fan can rotate forwards and reversely, and when the circulating fan rotates forwards, heat released by the condenser through the radiators is blown downwards into the drying room from the rear vent of the partition plate under the action of the circulating fan and then upwards enters the air duct from the front vent of the partition plate to form forward circulating air flow; when the circulating fan rotates reversely, the heat released by the condenser through the radiator is blown downwards into the drying room from the front vent of the partition plate under the action of the circulating fan, and then upwards enters the air channel from the rear vent of the partition plate to form reverse circulating air flow.
5. The intelligent air energy drying system of claim 4, wherein: install a plurality of hydrofuge machine on the roof in stoving room, the hydrofuge machine sets up in circulating fan's top, the hydrofuge machine is provided with the hydrofuge door.
6. The intelligent air energy drying system of claim 1, wherein: a control room is arranged on one side of the drying room, and the control system is arranged in the control room; the control system comprises a control mainboard and a touch panel, wherein the control mainboard is electrically connected with the touch panel through a data line; the control main board is provided with an MCU (microprogrammed control unit), and the MCU is electrically connected with a plurality of protection switches, a humidity sensor and a rectification filter switch circuit; the touch panel comprises a display screen and a touch input device, wherein the touch input device comprises an on-off key, a + key, a-key, a function key and a timing key.
7. The intelligent air-energy drying system according to any one of claims 1-6, wherein: the steam pipeline is arranged on the inner sides of the left side plate, the right side plate and the rear side plate, and a plurality of steam jet holes are arranged on the steam pipeline.
8. The intelligent air-energy drying system according to any one of claims 2-5, wherein: the lower end of the front side of the drying room is provided with a slide rail, the lower end of the front door is in sliding fit with the slide rail, so that the front door can move along the slide rail to open or close the drying room, and a sealing strip is arranged at the front side frame of the drying room and used for achieving sealing between the front door and the inside of the drying room; and heat insulation cotton is respectively arranged in the left side plate, the right side plate, the rear side plate, the top plate and the front door.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109813064A (en) * | 2019-03-15 | 2019-05-28 | 东莞市国福节能工程有限公司 | Intelligent air energy drying system and its furnace drying method |
CN113424865A (en) * | 2021-08-03 | 2021-09-24 | 四川述吉农业发展有限公司 | Morchella drying room |
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2019
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109813064A (en) * | 2019-03-15 | 2019-05-28 | 东莞市国福节能工程有限公司 | Intelligent air energy drying system and its furnace drying method |
CN109813064B (en) * | 2019-03-15 | 2024-07-16 | 东莞市国福节能工程有限公司 | Intelligent air energy drying system and drying method thereof |
CN113424865A (en) * | 2021-08-03 | 2021-09-24 | 四川述吉农业发展有限公司 | Morchella drying room |
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