KR20170089370A - Bluetooth and Internet radio operation control possible material dryer - Google Patents

Abstract

The present invention relates to a smashing and drying machine operated and controlled through Bluetooth and the Internet, capable of accurately maintaining drying efficiency even when drying various kinds of ingredients at the same time. As solar heat is used for a part of power or the whole power, the efficiency of energy consumption is overall maximized to make an economical contribution. Moreover, the present invention is capable of delivering an equal amount of heat in a drying space to each of the ingredients by inducing a position of each of the ingredients to be repeatedly changed, thereby improving the entire drying efficiency.

Description

Bluetooth & Internet Operation Controlled Grinding & Drying {Bluetooth and Internet radio operation control possible material dryer}

The present invention relates to a food material drying apparatus for drying and treating moisture contained in a drying material by heating in a state where a drying material requiring drying storage is housed in various crops harvested from a home or a farmhouse ,

As a result of the continuous circulation of the drying materials during the drying process, the heat inside the drying space is uniformly transferred to each drying material, thereby improving the overall drying efficiency and shortening the drying time.

In addition, the heat generated by the internal heater is spread uniformly throughout the drying space, thereby enhancing the drying efficiency of the drying material.

It is a technology that improves the overall energy efficiency by enhancing the economical efficiency by allowing the solar energy to supply the electric energy required for heat generation of the heater by using the solar heat.

In addition, if the installation is completed or other troubles occur, the relevant items are automatically transmitted to users via the Internet, and the user can control the operation from a remote place over the Internet, thereby improving the overall usability It is a technology.

In addition, the drying start point and the drying completion point are separately checked for each drying material, and the guide signal is transmitted to the user individually for each drying material, thereby improving the overall convenience.

Generally, it is dried and used as a food material, such as red pepper, seagrass, radish and mushroom harvested at home or farmhouse.

Especially in recent years, due to the tendency of well-being culture, the use of chemical seasoning in the home is excluded, and natural seasoning, which is formed by drying food materials such as crops and then grinding into powder form, is widely used. Trend.

Generally, a crop drying apparatus used in a home or a general farmhouse is provided with an electric heater provided at one side of a drying space formed inside the main body to heat the inside air. In this process, the drying material such as crops, So that drying is performed by the internal air heated by the electric heater.

However, in this conventional technique, since the drying material is positioned in a state where it is fixed on each lathe, the closer to the electric heater the drying material, the higher the drying rate.

Therefore, the drift rate of the drying material must be severely deviated according to the distance from the electric heater among the entire drying materials, which results in deterioration of the drying quality.

In addition, since each of the drying materials is located in a fixed position, a drift rate deviation occurs between the surface facing the heater and the surface facing the heater among the surfaces of the respective drying materials. Therefore, It is too cumbersome to change the position.

When various kinds of dry materials are dried together, the drying time varies depending on the type of each dry material. However, the prior art merely performs a drying function, and the check of the drying time, the estimated drying time, Only the user has to judge it.

Therefore, when the types of the drying materials are various, it is difficult to individually check the drying time for each of the drying materials, so that substantially all of the drying materials for each type are separately dried, which is an increase factor of the drying time .

The present invention has been made to solve the above-mentioned problems of the prior art,

The drying start time, the drying expectation time, and the drying completion time are memorized for each drying material so that the drying time of each drying material is individually checked, and the completion guide signal is wirelessly transmitted to the user through the Internet follow,

Even if various kinds of drying materials are simultaneously dried at all times, it is not necessary for the user to directly memorize the drying completion time of each drying material, so that it is possible to maintain accurate drying efficiency even if various kinds of drying materials are simultaneously dried.

In addition, it is possible to wirelessly transmit the guide signal for generating the completion of drying and other trouble signals to the user's mobile phone or the like via the Internet, and conversely, the user can remotely control the operation control signal by wirelessly transmitting the operation control signal through the mobile phone. So that the usability can be improved.

When the drying of all the drying materials is completed, the control unit checks the electric power and automatically cuts off the power supply, thereby preventing damage to the drying material due to overheating of the electric heater and also the possibility of fire.

 In addition, the connection between each sensor, the driving motor, the electric heater and the control unit for preventing the overheating is mutually wirelessly connected through the Bluetooth technology, thereby minimizing the electric wiring structure, thereby simplifying the overall structure and lowering the manufacturing cost .

And by using solar heat to cover some or all of the necessary power, it can maximize the efficiency of energy consumption as a whole and help it economically.

In addition, by inducing the positions of the respective drying objects to be changed repeatedly during the drying process, the heat in the drying space is uniformly transferred to all the drying objects, thereby improving the overall drying efficiency.

According to the present invention,

A drying space is formed in the inside of the drying space, and an opening / closing door is installed on the front side so that the drying space can be opened and closed and an exhaust port is formed at an upper side, a device space is formed inside the drying space, A drying case in which a guide hole communicating with the apparatus space is formed in a rail structure in the form of an infinite track, and a heat radiation hole is formed at an upper surface, a lower surface, left and right sides of the drying space, A drive sprocket connected to the motor shaft of the drive motor and rotated together with the drive sprocket; a drive motor for driving the drive sprocket in the apparatus space at the upper end of the stationary frame, A plurality of driven sprockets arranged in an array, And is a bar type which is wound around the driving sprocket and the respective driven sprockets at the same time to form an endless track shape and which is moved in the form of an endless track when the driving sprocket rotates by the driving motor. A connecting bar protruding from the front side of the moving chain and having a front end portion passing through the guide hole and located in the drying space, a first magnet embedded in the top surface of the connecting bar, And a rear lower surface is seated on the first magnet of the connecting bars to be integrally connected to each other, and the connecting bars are integrally connected to each other, In the course of moving along the movement path of the moving chain Wherein the plurality of drying chambers are buried in the bottom surface of each drying compartment at a position where they are seated on the first magnet of each connecting bar and have a polarity opposite to that of the first magnet, And a second magnet which is attached to the first magnet by a magnetic force so that each of the drying chambers can be detachably and magnetically attached to the respective connecting bars on the respective connecting bars, An electric heater disposed in the space of the drying space outside and emitting heat by self-heating by an external power source; an air intake fan disposed in the space outside the drying space inside the drying case to discharge air by sucking outside air; The heat generated by the heater is transmitted to the inside of the drying space through each of the heat dissipating holes in the drying case And a hollow tube having openings at both ends of the left and right sides. In the state of being positioned in the drying space, one end is connected to the peripheral surface of each of the heat dissipating holes, and the diameter of the funnel is increased toward the other end. A diffusion induction duct for guiding the heat discharged through the heat dissipating hole to be diffused in the drying space, and a diffusion induction duct located in the drying space, wherein the temperature in the drying space is constantly sensed to check whether the temperature is exceeded And a second Bluetooth transceiver for wirelessly connecting the electric heating sensor and the second Bluetooth transceiver to the overheat sensing sensor. The overheat sensing sensor is disposed outside the drying case, And the electric heating heater The controller automatically cuts off the supplied power to automatically shut off the operation of the electric heating heater and supplies the drive motor with the drive motor when the detection signal received through the overheat detection sensor is wirelessly connected to the drive motor through the third Bluetooth transceiver, A main controller for automatically shutting down the power source to automatically shut off the driving motor after a predetermined time, a Wi-Fi terminal capable of transmitting and receiving a Wi-Fi internet signal located outside the drying case, a Wi- And is located outside the drying case. The type of the drying material to be inputted into each drying box is memorized, and the proper drying time according to the drying material is memorized. The drying time of the drying material Based on this check, A memory control unit for wirelessly transmitting a drying completion signal of the drying material to the user's mobile phone via the Wi-Fi internet network when the drying completion time is reached after the completion of drying of the material, and a control unit connected to the outside of the drying case, A solar collector plate, a solar collector plate connected to the solar collector plate to convert solar energy stored in the solar collector plate into electrical energy, and stores the stored electrical energy in a state of being connected to the main control unit through the main controller, And a solar energy supply unit for transmitting the solar energy to the sensor and the memory control unit.

According to the present invention,

Since each drying compartment is continuously moved in the drying space through the driving motor and the moving chain in a state where the drying material is accommodated in each drying compartment, the respective drying materials accommodated in the respective compartment are also moved together, The heat is uniformly transferred to each drying material, thereby improving the overall drying efficiency.

Further, each drying box can be easily attached to and detached from each moving bar through magnetic force between the first magnet and the second magnet, so that the drying material can be easily received and withdrawn.

The heating temperature of the drying space is constantly sensed by the overheat sensor. If the inside temperature of the drying space exceeds the proper level, it is sensed and at the same time, the operation of the electric heating heater is automatically stopped through the main control valve, It is possible to prevent the drying material from being damaged or the possibility of fire.

When the heating of the heating heater is stopped, the driving motor is further operated for a predetermined time through the main control unit so that the drying motor is stopped. As a result, the drying chamber is moved within the drying space for a certain period of time after the heating of the electric heating heater is stopped, The additional drying of the drying material can be sufficiently carried out by using the remaining heat, so that the heating efficiency is improved and the energy consumption efficiency is also improved.

Then, when the proper amount of drying time for various kinds of dry materials is memorized in the memory control unit, the memory control unit checks the proper drying time of each drying case, When the target drying time of the material reaches, the corresponding notification signal is transmitted to the user's mobile phone through the Wi-Fi internet network,

Even if various kinds of dry materials are dried at the same time, the user can easily confirm the completion time of each dry material, and even if the user does not reside around the heating device, It also has an effect.

Fig. 1 is a cross-
Fig. 2 is a cross-
3 is a cross-
4 is an enlarged cross-sectional view

Hereinafter, a detailed description of the present invention will be given through the embodiments shown in the drawings.

The material drier capable of wirelessly controlling operation via Bluetooth and the Internet according to the present invention comprises a drying case 1 and a stationary frame 8, a driving motor 9, a driving sprocket 10, a driven sprocket 11 A moving chain 12, a connecting bar 13, a first magnet 14, a drying chamber 15, a second magnet 16, an electric heating heater 17, a hot air supply fan 18, A duct 19, an overheat sensor 20, a main control unit 21, a Wi-Fi terminal 25, a memory control unit 26, a solar condenser 27 and a solar energy supply unit 28.

The main structure of the present invention will be described sequentially.

First, the drying case 1 is an element for providing a space necessary for heating the drying material 29 and serving as an overall casing.

The drying case 1 is in the form of a box in which four sides are closed and a drying space is formed therein, and on the front side, an opening and closing door 3 for opening and closing the drying space 2 is installed to open and close the drying space.

In addition, an air outlet 4 is formed at one side of the upper part of the drying case 1 to continuously increase the pressure of the air in the drying space.

A device space 5 for installing a driving motor 9 and a moving chain 12 to be described later is formed in the rear side of the drying space 2 of the drying case 1, A guide hole 6 serving as a movement path of each connecting bar 13 to be described later has a rail shape in the form of an endless track and is formed to communicate with the apparatus space.

The heat radiation holes 7 for allowing the heat generated from the electric heating heaters 17 to be described later to flow into the drying space 2 are spaced apart from each other in the upper and lower surfaces and left and right sides of the drying case 1 .

For reference, the size and shape of the drying case 1 can be variously modified depending on the use place.

The drying case 1 is provided with a fixed frame 8.

The fixed frame 8 is an element serving as a skeleton for fixedly mounting the drive motor 9 and the driven sprocket 11 to be described later.

This fixed frame is positioned such that the rectangular frame crosses the apparatus space 5 of the drying case 1 up and down.

In this state, the fixed frame 8 is provided with the drive motor 9.

The drive motor 9 is an element that provides the driving force necessary for the position movement of the drying chamber 15 to be described later

The drive motor 9 is an electric motor that is generally rotatable in both directions and is fixedly mounted on the upper end of the fixed frame 8, and is positioned such that the motor shaft faces forward.

At this time, a driving sprocket 10 is installed on the motor shaft of the driving motor 9, and the driving sprocket 10 drives the moving chain 12, which firstly outputs the rotational force of the driving motor 9 to move the moving chain 12 And is rotated together with the motor shaft of the drive motor 9.

In this state, the stationary frame 8 is provided with a driven sprocket 11.

The driven sprocket 11 is an element which serves as a guide for a stable installation of the moving chain 12 to be described later and for allowing the moving chain 12 to move smoothly in an endless track form.

These driven sprockets 11 are arranged at the upper end portion and the both side portions and the lower end portion of the fixed frame 8 in the apparatus space 5 of the drying case 1. [

In this state, the moving chain 12 is wound around the driving sprocket 10 and each driven sprocket 11.

The moving chain 12 is a component for simultaneously moving each drying chamber by using the rotational force of the driving motor 9 while mounting each drying chamber to be described later.

The moving chain 12 is in the form of a sprocket chain in the form of a general endless track and is wound around the drive sprocket 10 and each driven sprocket 11 at the same time to form an endless track and is driven by the drive motor 9 to rotate the drive sprocket 10 And has a structure that rotates in the form of an infinite orbit during rotation.

In this state, a connecting bar (13) is connected to the moving chain (12).

The connecting bar 13 is an element for engaging the moving chain 12 and each drying compartment 15 described below.

The connection bar 13 is formed in a square bar shape having a longitudinal direction and has a rear end protruding toward the front side in a state of being connected to the front end of the moving chain and having a front end portion passing through the guide hole 6 of the drying case 1 So as to be positioned in the drying space 2.

Since the connecting bars 13 are spaced apart from each other along the forming path of the moving chain, the connecting bars 13 are moved along the forming path of the guide hole 6 in the guide hole 6 when the moving chain 12 is moved. And simultaneously move in an infinite orbit form.

The connecting bar 13 is provided with a first magnet 14.

The first magnet 14 is a general permanent magnet type and is embedded on the upper surface of each connecting bar 13 so as to guide the drying box 15 to be described later to be easily detached and attached to the connecting bar 13 through magnetic force Only the upper surface is exposed in the form of being exposed to the outside.

In this state, a drying box 15 is connected to each connecting bar 13.

The drying compartment 15 is the element accommodating the desiccant material 29 to be dried.

The drying chamber 15 is formed in a box shape having a space formed therein and has a mesh structure at four sides and a door 30 is formed at the front side and a rear lower side is connected to the first magnet 14). ≪ / RTI >

At this time, a second magnet 16 having a polarity opposite to that of the first magnet 14 is embedded in the lower surface of each drying compartment 15 so as to be seated on the first magnet 14, In a simple one-touch manner by the magnetic force between the first magnet 14 and the second magnet 16 in the process of being placed on each connecting bar 13, .

With this structure, each drying compartment 15 moves simultaneously along the same path in the process of moving the connecting bars 13 along the forming path of the guide hole 6 through the moving chain 12. [

In this state, the drying case 1 is provided with the electric heater 17.

The electric heating heater 17 is an element serving as a supply source for supplying the heat required for drying the drying material 29.

The electric heater 17 is generally formed in a form of self-heating when an external power source is applied, and is realized in the form of a coil, a rod, or a surface heating element.

The electric heating heater 17 is located in the space of the outside of the drying space 2 in the drying case 1 and generates heat by the external power source to radiate heat, And is supplied into the drying space (2) through the diverging hole (7).

At this time, a hot air supply fan (18) is installed in the drying case (1).

The hot air supply fan 18 is an element for guiding the heat radiated through the electric heater 17 to be forced into the drying space 2.

The hot air supply fan 18 is located in the outer space of the drying space 2 in the inside of the drying case 1 and is in the form of an intake fan for sucking and discharging outside air. Is guided to be supplied into the drying space through each of the heat dissipating holes (7) in the drying case (1).

In this state, the drying case 1 is provided with the diffusion induction duct 19.

The diffusion induction duct 19 is an element that induces heat to be distributed throughout the inside of the drying space 2 in the process of passing the heat through each of the heat dissipating holes 7.

The diffusion induction duct 19 is a hollow tube having openings at both ends of the left and right sides. The diffusion induction duct 19 is located in the drying space 2 and has one end connected to the peripheral surface of each heat dissipating hole 7, .

Therefore, the heat that has passed through each of the heat dissipating holes 7 and flows into the drying space 2 is diffused in the process of passing through each of the diffusion induction ducts 19, and eventually passes through the diffusion induction duct 19, So that the heat discharged from each of the diffusion induction ducts 19 is uniformly distributed throughout the drying space 2.

In this state, the overheat sensor 20 is installed in the drying case 1

The overheat detection sensor 20 is an element for preventing the temperature in the drying space 2 from rising excessively during the drying process in the drying space 2.

The overheat detection sensor 20 is a type of temperature sensor using general electricity and detects the temperature in the drying space 2 at all times in a state of being located on the wall surface of the drying space 2 and checks whether or not the temperature exceeds the proper temperature , And when the temperature exceeds the appropriate level, the overheating signal is transmitted to the main control unit 21, which will be described later.

In this state, the drying case 1 is provided with a main control unit 21.

The main control unit 21 automatically stops the operation of the electric heater 17 when receiving an overheating signal from the overheat sensor 20, and automatically stops the drying operation when the drying time set by the self timer function has elapsed And stops the operation of the apparatus automatically.

The main control unit 21 has a cpu shape having a general electric control function, and is installed and installed in the drying case 1 through an electric circuit board designed according to the cpu.

At this time, the main controller 21 is wirelessly connected to the overheat sensor 20 through the first Bluetooth transceiver 22 and wirelessly connected to the electric heater 17 via the second Bluetooth transceiver 23.

Accordingly, upon receiving the overheated signal sensed by the overheat sensing sensor 20, the electric heater 17 is not operated as the wireless signal is transmitted to the electric heater 17.

In addition, a timer is provided to detect a normal drying time and to stop the entire drying operation automatically.

At this time, since the main control unit 21 is wirelessly connected to the driving motor 9 and the third Bluetooth transceiver 24, the main control unit 21 wirelessly operates the driving motor 9 when the sensing signal received through the overheat detection sensor 20 is input The operation of the driving motor 9 is stopped by stopping the operation of the driving motor 9 without stopping the operation of the driving motor 9 for a predetermined period of time, The drying material remaining in the drying space is used to induce additional drying of the drying material in each drying compartment.

In this state, the drier case 1 is provided with a Wi-Fi terminal 25.

The WiFi terminal 25 is connected to the wireless Internet network and enables Internet connection through each wireless Internet network.

In this state, the drying case 1 is provided with a memory control section 26. [

The memory control unit 26 memorizes the type of the drying material 29 contained in each drying compartment 15 and the optimum drying time of the corresponding drying material 29 and individually checks the drying completion time for each of the preceding materials And simultaneously transmits a drying completion signal to the user's cellular phone 30.

The memory control unit 26 is wirelessly connected to the Wi-Fi terminal 25 via a wireless Internet network. The memory control unit 26 is located outside the drying case 1 and stores the type of the drying material to be supplied to the drying case.

In addition, the optimum drying time for each drying chamber is memorized, and the starting point of drying of each drying chamber is checked, and based on this, the time for completion of drying of the relevant drying material is determined. And transmits a dry completion signal of the material wirelessly to the user's cellular phone 30 through the Wi-Fi internet network.

In this state, the solar condenser plate 27 is installed in the drying case.

The solar collector plate 27 collects sunlight for use as electric energy and is formed in the form of a general solar collector plate 27 and integrally connected to the outside of the drying case 1, As shown in FIG.

A solar energy supply unit 28 is connected to the solar light collecting plate 27.

The solar energy supply unit 28 converts solar energy collected through the solar light collecting plate 27 into electric energy and stores electric energy to each component.

The solar energy supply unit 28 is connected to the solar light collecting plate 27 to convert solar energy stored in the solar light collecting plate 27 into electric energy and supplies the electric energy to the main control unit 21, the memory control unit 26, the electric heating heater 17, , A drive motor (9), and the like.

According to this structure, the present invention can supply electric power through auxiliary electric energy through sunlight in addition to general external power source.

One; Drying case 2; Drying space
3; an opening / closing door 4;
5; device space 6; guide ball
7; Heat radiating ball 8; Fixed frame
9, a drive motor 10, a drive sprocket
11, a driven sprocket 12, a moving chain
13: connecting bar 14: first magnet
15; Drying 16; Second magnet
17: electric heater 18; hot air supply fan
19; diffusion induction duct 20;
21, a main control unit 22, a first Bluetooth transceiver
23, a second Bluetooth transceiver 24, a third Bluetooth transceiver
25, a Wi-Fi terminal 26,
27: solar collector plate 28;
29, a drying material 30, a mobile phone
31, a crushing case 32,
33, a crushing cover 34,
35; outlet 36;
37; inlet duct

Claims (1)

A drying space is formed in the inside of the drying space, and an opening / closing door is installed on the front side so that the drying space can be opened and closed and an exhaust port is formed at an upper side, a device space is formed inside the drying space, A rear case having a rear side wall formed with a guide hole communicating with the apparatus space and having a rail structure in the form of an endless track, a drying case formed on the upper and lower surfaces of the drying space,
A fixing frame positioned in the apparatus space of the drying case,
A drive motor located at an upper end of the stationary frame in the apparatus space,
A drive sprocket connected to the motor shaft of the drive motor and rotated together,
A plurality of driven sprockets arranged at both upper and lower ends of the stationary frame upper portion in the apparatus space,
A driving sprocket for driving the driving sprocket and the driven sprocket, the driving sprocket being wound on the driven sprocket at the same time to form an endless track,
A connecting bar arranged at a distance from the front side of the moving chain and projecting forward from the front side of the traveling chain, the front end of the traveling chain passing through the guide hole and located in the drying space,
A first magnet embedded in the upper surface of the connecting bar,
And a rear lower surface is seated on the first magnet of the connecting bars to be integrally connected to each other, and the connecting bars are integrally connected to each other, A plurality of drying chambers which are moved along the movement path of the moving chain together with the movement of the moving chain along the moving path,
Wherein the first and second magnets are mounted on a first magnet of each of the connecting bars on the lower surface of each of the drying compartments and have a polarity opposite to that of the first magnet, And the second magnet is attached to the first magnet by a magnetic force so that each of the drying chambers can be detachably and magnetically attached to the respective connecting bars,
An electric heater disposed in the space of the drying space outside the drying case and self-heating by the external power source to radiate heat,
And an air intake fan which is located in a space outside the drying space of the inside of the drying case and which discharges air by sucking outside air, A hot air supply fan for guiding the air to be supplied to the outdoor heat exchanger,
A hollow tube having both ends opened at both ends thereof and having a funnel shape with one end connected to the peripheral surface of each of the heat dissipating holes in a state of being positioned in the drying space and having a larger diameter toward the other end, A diffusion induction duct for inducing the heat to be discharged through the drying space to be diffused in the drying space,
An overheat detecting sensor which is located in the drying space and which always detects the temperature in the drying space and checks whether the temperature exceeds the proper temperature,
A second Bluetooth transceiver connected to the electric heating sensor via a second Bluetooth transceiver, the second electric transducer being connected to the electric heating sensor via a second Bluetooth transceiver, Receiving the signal and automatically shutting off the power supplied to the electric heating heater to automatically stop the operation of the electric heating heater and transmitting the driving motor to the driving motor via the third Bluetooth transceiver, A main controller for automatically shutting off the power supplied to the drive motor when the detection signal is inputted so that the drive motor automatically stops operating after a predetermined time,
A Wi-Fi terminal capable of transmitting and receiving a Wi-Fi internet signal located outside the drying case,
The wiper device is wirelessly connected to the Wi-Fi terminal via Wi-Fi, and is located outside the drying case. The type of the drying material to be inputted into each drying box is memorized. The proper drying time according to the drying material is memorized. Based on this, it is determined whether the drying material is completely dried based on the starting point of drying of the drying material. When the drying material is completed, the signal indicating completion of drying of the drying material is transmitted wirelessly to the user's mobile phone through the Wi- A memory control unit,
A solar collecting plate connected to the outside of the drying case for collecting solar light,
A solar collector plate connected to the solar collector plate to convert solar energy stored in the solar collector plate into electric energy, and stores the stored electric energy in the state of being connected to the main controller through an electric heater, an electric heater, The solar energy supply unit
And a control unit for controlling the operation of the crushing and drying unit.

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