KR20210112920A - Green house Switchgear System - Google Patents

Abstract

The present invention relates to a greenhouse opening/closing system capable of significantly reducing a cost required for construction. According to the present invention, the greenhouse opening/closing system including a plurality of switches for opening and closing a light-shielding film of a plastic greenhouse and a controller for controlling operations of the switches includes: a rectifier circuit; a connection wire; a converter; a power supply unit; and a rotation control unit.

Description

Green house switchgear system

The present invention relates to a greenhouse switching system, and more particularly, by converting external AC 220V power transmitted to a controller into DC 220V through a rectifying circuit and transmitting it to each switchgear, power is transmitted from the controller to each switchgear It is possible to reduce the thickness of the connecting wire to be used, which greatly reduces the cost of constructing the greenhouse switching system, and also converts the voltage of DC 220V to a low voltage of DC 24 to 110V through the converter installed in the switchgear. A greenhouse opening and closing system that can induce easy construction and management of a greenhouse opening and closing system by solving various problems required for manufacturing a small motor using high voltage because the coil wound around the rotor of the driving motor installed in the blade can be formed thick is about

In general, a greenhouse such as a greenhouse refers to a greenhouse covered with a plastic film to grow crops such as vegetables and fruits. Here, an opening/closing system for opening and closing ventilation members (hereinafter, referred to as 'light-shielding curtains') such as ventilation windows, warming carts, and light-shielding curtains is installed in order to control the temperature inside the plastic house.

A conventional greenhouse opening/closing system is configured to include a plurality of switchgear installed on a plurality of light-shielding films of a plastic house to perform opening and closing of the light-shielding film, respectively, and a controller for controlling the operation of the switchgear.

Here, the driving motor performing the operation in the switch is usually connected to three power lines due to the use of AC 380V power, and three wires for controlling the forward and reverse directions of the driving motor for opening and closing the light shielding film are connected. Due to the structure of the switchgear, the structure of the switchgear is complicated, and there is a problem that the manufacture and operation of the switchgear is very inconvenient.

In order to solve the above problems, if a DC 220V driving motor is used, the use of two power lines is required to form the structure of the switchgear rather simply, but it is wound around the rotor of the driving motor by the high voltage of 220V. has the problem that it is too difficult to manufacture a small motor used for switchgear because the thickness of the coil is very thin Due to the low insulation resistance, there is a risk of electric shock due to a short circuit, so a separate safety device is required.

Here, there is a method to solve the above problems by forming a thick coil wound around the rotor using a motor operated at a low voltage such as DC 24V for the driving motor of the switchgear, but in this case, each There was a problem that too much cost was required to build a greenhouse opening and closing system because the thickness of the wire that transmits power to the switchgear was very thick.

Therefore, there is a need to develop a greenhouse opening/closing system that can solve the above complex problems and can be operated stably at low cost.

The present invention has been proposed to solve the various problems as described above, and its purpose is to convert the external AC 220V power transmitted to the controller into DC 220V through a rectifier circuit and transmit it to each switchgear in the controller. It is possible to form a thin connecting wire that transmits power to the switchgear of By converting to , the coil wound around the rotor of the drive motor installed in the switchgear can be formed thick, solving various problems required for the manufacture of small motors using high voltage, and inducing easy construction and management of the greenhouse switchgear system. It is to provide a greenhouse opening and closing system.

Furthermore, it is to provide a greenhouse opening and closing system that can construct the structure of the switchgear more simply by simply controlling the rotational direction of the drive motor in a way that converts the polarity of the power transmitted to the drive motor of the switchgear through the rotation controller.

A greenhouse opening and shutting system according to the present invention for achieving the above object is a greenhouse opening and closing system comprising a plurality of switchgear for opening and closing a light-shielding film of a plastic house, and a controller for controlling the operation of the switchgear,

A rectifier circuit for converting AC 220V power supplied to the controller into DC 220V power; A converter that converts the power of DC 220V transmitted through the connection wire into DC 24 to 110V so that the low voltage is supplied to the driving motor of the switchgear; and the power supplied through the converter is transmitted to the switchgear , a first wire electrically connecting the converter and the driving motor to which a positive or negative pole is applied, and electrically connecting the converter and the driving motor. A power supply including a second wire to which an anode is applied when a cathode is applied; and a rotational direction of the driving motor that is supplied with power through the power supply by controlling the electrodes applied to the first and second wires of the power supply It characterized in that it is configured to include; a rotation control unit for controlling the.

In addition, the first wire and the second wire of the power supply part are wires connected to the driving motor,

The rotation control unit includes a (-) th 3-1 wire connected to the converter to which a negative pole is applied, a (+) 4-1 th wire connected to the converter to which a positive pole is applied, and the (-) 3-1 th wire A (-) 3-2 wire branched from an electric wire to which a negative pole is applied, a (+) 4-2 wire branched from the (+) 4-1 wire to which a positive pole is applied, and one end of the first wire is electrically connected and fixed, and the other end is connected to the (-) No. 3-1 wire, and when power is supplied and operated, a first relay switch connected to the (+) No. 4-2 wire, and one end of the first relay switch A second relay switch electrically connected to the first wire and fixed, the other end connected to the (+) No. 4-1 wire, and connected to the (-) No. 3-2 wire when power is supplied and operated; 1, 2, a zener diode supplying operating power to the relay switch, and the operation is controlled by the controller, and the electrical connection between the rectifier circuit and the converter and the rectifier circuit and the zener diode is turned ON-OFF. ), and when the connection between the rectifier circuit and the converter and the rectifier circuit and the Zener diode is turned on, the DC 220V power converted through the rectifier circuit is transmitted to the converter, and a reverse voltage is formed in the Zener diode. The operation is controlled by the controller and the rectifier circuit and the converter, and the electrical connection between the rectifier circuit and the zener diode is turned ON-OFF, and the rectifier circuit and the converter and the rectifier circuit are turned on and off. When the connection of the Zener diode and the Zener diode is turned on, the DC 220V power converted through the rectifier circuit is transmitted to the converter, and a constant voltage is formed in the Zener diode, including a second switch unit for operating the first and second relay switches. It is characterized in that it is done.

As described above, according to the greenhouse switching system according to the present invention, the external AC 220V power transmitted to the controller is converted to DC 220V through the rectifying circuit and transmitted to each switchgear, thereby transmitting power from the controller to each switchgear. It is possible to reduce the thickness of the connecting wire to be used, which greatly reduces the cost of constructing the greenhouse switching system, and also converts the voltage of DC 220V to a low voltage of DC 24 to 110V through the converter installed in the switchgear. The coil wound around the rotor of the drive motor installed in the blade can be formed thick, so it has the effect of inducing easy construction and management of the greenhouse opening and closing system by solving various problems required for the manufacture of small motors using high voltage. .

Furthermore, there is an effect that the structure of the switchgear can be constructed more simply by simply controlling the rotational direction of the drive motor by changing the polarity of the power transmitted to the drive motor of the switchgear through the rotation controller.

1 is a conceptual diagram of a greenhouse opening and closing system according to an embodiment of the present invention;
Figure 2 is a circuit diagram for explaining the greenhouse opening and closing system shown in Figure 1;
3 is a view for explaining the operation of the greenhouse opening and closing system shown in FIG.

A greenhouse opening and shutting system according to a preferred embodiment of the present invention will be described in detail based on the accompanying drawings. Detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the gist of the present invention will be omitted.

1 to 3 are diagrams showing a greenhouse opening and closing system according to an embodiment of the present invention, FIG. 1 is a conceptual diagram of the greenhouse opening and closing system according to an embodiment of the present invention, and FIG. 2 is the greenhouse opening and closing system shown in FIG. A circuit diagram for explanation, FIG. 3 is a diagram for explaining the operation of the greenhouse opening and closing system shown in FIG. 1 , respectively.

As shown in the figure, the greenhouse opening and closing system 100 according to the embodiment of the present invention includes a plurality of switchgear 2 that opens and closes the light shielding film 1 of the plastic house, and controls the operation of the switchgear 2 In the greenhouse opening and closing system including the controller (3),

A rectifier circuit 10 , a connecting wire 20 , a converter 30 , a power supply unit 40 , and a rotation control unit 50 are further included.

As shown in FIG. 2 , the rectifier circuit 10 converts the AC 220V power supplied to the controller 3 to DC 220V power.

In general, when AC power is supplied to the drive motor 4 of the switch 2 through the controller 3, three wires are connected to connect the three phases, and for controlling the rotation direction of the drive motor 4 Since the electrical connection structure of the switch 2 is very complicated, such as three wires connected by a device such as a switch, manufacturing and operation may be somewhat inconvenient.

Therefore, the rectifier circuit 10 converts the AC 220V power supplied to the controller 3 into DC 220V so that the power transmitted through the controller 3 is transmitted through two wires, so that the switchgear (2) The internal electrical connection structure can be formed very simply.

Furthermore, it is possible to control the rotation direction of the driving motor 4 in a way that changes the polarity of the electrode supplied to the electric wire through the rotation control unit 50 to be installed later, so that the electrical connection inside the switchgear 2 is further improved The structure can be configured simply, which will be described in detail in the rotation control unit 50 below.

As shown in FIGS. 1 and 2 , the connection wire 20 transmits the DC 220V power converted in the rectifier circuit 10 to each of the switchgear 2 .

That is, in order to transmit the power converted into DC 220V through the rectification circuit 10 to a plurality of switchgear 2 installed in the plastic house, It is required to use, at this time, due to the nature of using a high voltage of 220V, a wire with a small thickness can be used according to Ohm's Law. This can lead to a significant reduction in the usability of the system.

As shown in FIG. 2 , the converter 30 is installed in the switchgear 2 and converts the power of DC 220V transmitted through the connection wire 20 into DC 24 to 110V of the switch 2 . A low voltage is supplied to the driving motor (4).

That is, as shown in FIGS. 3A and 3B, the reason for converting the DC 220V high voltage power that has passed through the rectifier circuit 10 to the DC 24 to 110V low voltage through the converter 30 will be described above. In the case of a small motor, the driving motor using a high voltage of DC 220V without conversion of the converter 30 has a very thin coil wound around the rotor due to the characteristic that the thickness of the wire used for high voltage is small (thin). Not only is it very difficult to manufacture, but it is also difficult to form and maintain the insulation coating of the coil, so a separate safety device is required. There were limits.

Therefore, the power transmitted from the controller 3 to the switch 2 is made to transmit a high voltage of DC 220V, so that the thickness of the connection wire 20 built from the controller 3 to the switch 2 is thinned. To reduce the cost required for system construction, the converter 30 converts the power supplied to the drive motor 4 of the switch 2 into a low voltage and supplies it to the coil wound around the rotor of the drive motor 4 . It induces the easy manufacture of low-cost small motors that can be applied and used in greenhouses at low manufacturing cost by securing the manufacturing convenience and safety of the motor by forming thick.

As shown in FIG. 2 , the power supply unit 40 transmits power supplied through the converter 30 to the switchgear 2 , and electrically connects the converter 30 and the driving motor 4 to each other. The first wire 41 to which a positive electrode ((+) electrode) or negative electrode ((-) electrode) is applied, and the first wire 41 for electrically connecting the converter 30 and the driving motor 4 ) includes a second wire 42 to which an anode is applied when an anode is applied, and a cathode is applied when a cathode is applied to the first wire 41 .

That is, as shown in FIG. 3A , when a negative pole is applied to the first wire 41 through the rotation controller 50 and a positive pole is applied to the second wire 42 at the same time, the drive motor 4 Rotating in the forward direction and vice versa, as shown in FIG. 3b , when a positive pole is applied to the first wire 41 and a negative pole is applied to the second wire 42 at the same time, the drive motor 4 rotates in the reverse direction. do.

As shown in FIG. 2 , the rotation control unit 50 supplies power through the power supply unit 40 by controlling the electrodes applied to the first and second wires 41 and 42 of the power supply unit 40 . By controlling the rotation direction of the driving motor 4 received,

The first wire 41 and the second wire 42 of the power supply unit 40 are wires connected to the driving motor 4,

A (-) 3-1 wire 51 connected to the converter 30 to which a negative pole is applied, a (+) 4-1 wire 52 connected to the converter 30 to which a positive pole is applied; The (-) 3-2 wire 53 branched from the (-) 3-1 wire 51 to which the negative electrode is applied, and the (+) 4-1 wire 52 branched from the positive electrode applied The (+) 4-2 wire 54 that becomes the first wire 54, one end is electrically connected to the first wire 41 and fixed, and the other end is connected to the (-) 3-1 wire 51, and the power is When it is supplied and operated, the first relay switch 55 is connected to the (+) 4-2 wire 54, and one end is electrically connected and fixed to the first wire 41, and the other end is the (+) A second relay switch 56 connected to the 4-1th wire 52 and connected to the (-) 3-2 wire 53 when power is supplied and operated, and the first and second relay switches ( A Zener diode 57 for supplying operating power to 55 and 56, and an operation controlled by the controller 3, the rectifier circuit 10, the converter 30, and the rectifier circuit 10 The electrical connection of the Zener diode 57 is turned on and off, and when the connection between the rectifier circuit 10 and the converter 30 and the rectifier circuit 10 and the Zener diode 57 is turned on, the The power of DC 220V converted through the rectifier circuit 10 is transmitted to the converter 30 , and the first switch unit 58 in which a reverse voltage is formed in the Zener diode 57 , and the controller 3 . The operation is controlled by the rectifier circuit 10 and the converter 30, and the electrical connection between the rectifier circuit 10 and the Zener diode 57 is turned ON-OFF, and the rectifier circuit When the connection between (10) and the converter (30) and the rectifier circuit (10) and the Zener diode (57) is turned on, the power of DC 220V converted through the rectifier circuit (10) is transmitted to the converter (30), a second switch unit ( 59) is included.

In order to open or close the light shielding film 1 of the plastic house through the driving motor 4 of the normal switch 2, bidirectional rotation of the driving motor 4 is required.

That is, when the forward rotation of the driving motor 4 is required to open the light blocking film 1 of the plastic house, the controller 3 turns on the first switch unit 58 as shown in FIG. 3A . ) to electrically connect the rectifier circuit 10 and the converter 30, at this time, a reverse voltage is formed in the Zener diode 57 connected to the rectifier circuit 10 through the first switch unit 58. Since the first and second relay switches 55 and 56 are not operated, the (-) 3-1 wire 51 connected to the converter 30 and the first relay switch 55 are connected to The first wire 41 is formed as a negative electrode, and at the same time the (+) 4-1 wire 52 connected to the converter 30 and the second wire 42 are connected to the second relay switch 56 . The driving motor 4 rotates in the forward direction while forming the anode.

At this time, in order to stop the opening of the light blocking film, the first switch unit 58 is turned OFF to cut off the power supplied to the driving motor 4 so that the opening of the light blocking film 1 is stopped. am.

Conversely, when the reverse rotation of the driving motor 4 is required to close the light blocking film 1 of the plastic house, the controller 3 turns on the second switch unit 59 as shown in FIG. 3b . ) to electrically connect the rectifier circuit 10 and the converter 30, at this time, a constant voltage is formed in the Zener diode 57 connected to the rectifier circuit 10 through the second switch unit 53. Since the first and second relay switches 55 and 56 are operated, the (-) 3-2 wire 53 and the second The relay switch 56 is connected so that the second wire 42 is formed as a negative electrode, and the (+) 4 - branched from the (+) 4-1 wire 52 connected to the converter 30 at the same time As the second wire 54 and the first relay switch 55 are connected to form the first wire 41 as a positive electrode, the driving motor 4 rotates in the reverse direction.

Therefore, the rotational direction of the driving motor 4 can be controlled in such a way that the electrodes applied to the first and second wires 41 and 42 of the power supply unit 40 are changed through the rotation control unit 50 . The electrical connection structure inside the switch 2 can be formed more simply.

The greenhouse opening/closing system 100 of the present invention configured as described above converts the external AC 220V power transmitted to the controller 3 into DC 220V through the rectifier circuit 10 and transmits it to each switchgear 2 By doing so, the thickness of the connecting wire 20 that transmits power from the controller 3 to each switch 2 can be formed very thin, so that it is possible to significantly reduce the cost of constructing the greenhouse opening and closing system, as well as the switch By converting the voltage of DC 220V to a low voltage of DC 24 to 110V through the converter 30 installed in (2), the coil wound around the rotor of the drive motor 4 installed in the switchgear 2 is thick. This has the effect of inducing easy construction and management of the greenhouse opening/closing system by solving various problems required for the production of a small motor using a high voltage in the prior art.

Furthermore, the structure of the switchgear 2 can be changed by simply controlling the rotational direction of the drive motor 4 in a way that converts the polarity of the power transmitted to the drive motor 4 of the switch 2 through the rotation control unit 50 . It has the effect of making it simpler to build.

Although the present invention has been described with reference to the embodiments shown in the accompanying drawings, which are illustrative and not limited to the above-described embodiments, those of ordinary skill in the art will realize that various modifications and equivalent embodiments are possible therefrom. point can be understood. In addition, it is a matter of course that modifications by those skilled in the art are possible within the scope that does not impair the spirit of the present invention. Accordingly, the scope of claiming the right in the present invention will not be defined within the scope of the detailed description, but will be limited by the claims and its technical spirit to be described later.

1. light shield 2. switch
3. Controller 4. Drive motor
10. Rectifier circuit 20. Connection wire
30. Converter 40. Power Supply
41. First Front 42. Second Front
50. Rotation control unit 51. (-) No. 3-1 wire
52. (+) 4-1 wire 53. (-) 3-2 wire
54. (+) 4-2 wire 55. 1st relay switch
56. Second relay switch 57. Zener diode
58. First switch unit 59. Second switch unit
100. Greenhouse opening and closing system

Claims (2)

In the greenhouse opening and closing system comprising a plurality of switchgear (2) for opening and closing the light shielding film (1) of a plastic house, and a controller (3) for controlling the operation of the switchgear (2),
a rectifier circuit 10 for converting AC 220V power supplied to the controller 3 into DC 220V power;
a connection wire 20 for transmitting the DC 220V power converted in the rectifier circuit 10 to each of the switchgear (2);
A converter that is installed in the switchgear 2 and converts DC 220V power transmitted through the connection wire 20 into DC 24 to 110V so that low voltage is supplied to the driving motor 4 of the switchgear 2 . (30);
The power supplied through the converter 30 is transmitted to the switchgear 2, and the converter 30 and the driving motor 4 are electrically connected, and a positive electrode ((+) electrode) or a negative electrode ((-) The first wire 41 to which the electrode) is applied, the converter 30 and the driving motor 4 are electrically connected, and when an anode is applied to the first wire 41, a cathode is applied and the first wire ( 41) a power supply unit 40 including a second wire 42 to which the positive electrode is applied when the negative electrode is applied; and
A rotation control unit that controls the electrodes applied to the first and second wires 41 and 42 of the power supply unit 40 to control the rotational direction of the driving motor 4 receiving power through the power supply unit 40 . (50); Greenhouse opening and closing system, characterized in that it is configured to include.
The method of claim 1,
The first wire 41 and the second wire 42 of the power supply unit 40 are wires connected to the driving motor 4,
The rotation control unit 50,
A (-) 3-1 wire 51 connected to the converter 30 to which a negative pole is applied;
A (+) 4-1 wire 52 connected to the converter 30 to which a positive pole is applied;
a (-) 3-2 wire 53 branched from the (-) 3-1 wire 51 to which a negative electrode is applied;
a (+) 4-2 wire 54 branched from the (+) 4-1 wire 52 to which an anode is applied;
One end is electrically connected to and fixed to the first wire 41, and the other end is connected to the (-) 3-1 wire 51, and when power is supplied and operated, the (+) 4-2 wire ( 54) and a first relay switch 55 connected to,
One end is electrically connected to and fixed to the first wire 41, and the other end is connected to the (+) 4-1 wire 52, and when power is supplied and operated, the (-) 3-2 wire ( 53) and a second relay switch 56 connected to,
a zener diode 57 for supplying operating power to the first and second relay switches 55 and 56;
The operation is controlled by the controller 3, and the electrical connection between the rectifier circuit 10 and the converter 30 and the rectifier circuit 10 and the Zener diode 57 is turned ON-OFF. ), and when the connection between the rectifier circuit 10 and the converter 30 and the rectifier circuit 10 and the Zener diode 57 is turned on, the DC 220V power converted through the rectifier circuit 10 is transferred to the converter ( 30), but a first switch unit 58 in which a reverse voltage is formed in the Zener diode 57;
The operation is controlled by the controller 3, and the electrical connection between the rectifier circuit 10 and the converter 30 and the rectifier circuit 10 and the Zener diode 57 is turned ON-OFF. ), and when the connection between the rectifier circuit 10 and the converter 30 and the rectifier circuit 10 and the Zener diode 57 is turned on, the DC 220V power converted through the rectifier circuit 10 is transferred to the converter ( 30), but a constant voltage is formed in the Zener diode (57), and a second switch unit (59) for operating the first and second relay switches (55, 56) is included. system.

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