KR20210029078A - electronic price display device based on indoor light energy harvesting - Google Patents

Abstract

The present invention relates to a technique which harvests a microunit current generated through an indoor light while the indoor light is turn on, and which uses the harvested power as an energy source for an event of changing the contents of electronic price display units and, more specifically, to a technique by which a solar cell stores a microunit current generated through an indoor light in a supercapacitor, and then performs an event of changing the contents of electronic price display units with the stored power when the event has occurred in the electronic price display units. In particular, the present invention relates to a technique capable of testing a device even before sufficient power is stored in a supercapacitor after the device is installed, by accommodating a separate test battery. According to the present invention, a voltage detection member, a leakage current blocking control member, and one or more capacitor switch members are provided, and thus in case that no current is generated from a solar cell member when an indoor light is turned off, power harvested to a supercapacitor is prevented from being leaked.

Description

Electronic price display device based on indoor light energy harvesting

The present invention relates to a technology for harvesting a micro-unit electric current generated through the indoor lamp while the indoor lamp is turned on, and using the harvested power as an energy source for a content change operation event of an electronic price display unit.

More specifically, in the present invention, when a solar cell accumulates a micro unit of current generated through indoor light to a super capacitor, and a content change operation event in the electronic price display unit occurs thereafter, the stored power supply is used for the change event. It relates to the technology that allows you to perform.

In particular, it relates to a technology that enables testing of a device even before sufficient power is stored in a super capacitor after installation of the device as it is configured to accommodate a separate test battery.

In general, information on the specifications and price of the products displayed are displayed on the shelves of the store.

In the past, because a one-time price tag was used, if the product specifications or price information on display is periodically changed, costs (e.g., paper, coatings, various consumables, designs) are incurred in response to the change. There was a drawback of creating a simple business time in which the employee had to manually replace the one-time price tag.

[Fig. 1] is an exemplary diagram showing a state of use of a general electronic price display device. As shown in [Fig. 1], the above disadvantages have been solved by placing a so-called electronic shelf label (ESL) on the shelves of the store. Problems arose.

[Fig. 2] is a block diagram of a conventional electronic price display device. Referring to FIG. 2, in general, an electronic price display unit (ESL) employs a so-called coin battery (30) that provides an energy source when a content change manipulation event occurs for the electronic price display unit 20, Considering that the life of the coin battery 30 is approximately 2 years, assuming that the electronic price indicator is used for about 10 years, one electronic price indicator takes approximately 5 coin batteries 30 for 10 years. .

In addition, there is a problem that the replacement defect rate of coin batteries is frequent, and as the so-called'RF CHIP' and'E-paper', which are the configurations of the ESL control unit 40 employed in ESL devices, are advanced, a battery with a larger capacity is required. There is also a problem.

Here, if the capacity of the battery is increased, the battery receiving member of the existing electronic price display may be changed accordingly, so if the so-called'RF CHIP' and'E-paper' are advanced, the electronic price indicator must be replaced at all. Can occur.

Accordingly, the problem of the prior art as described above is solved by harvesting the current of tens of micro units within the time when the indoor light used in the store is turned on, and then temporarily consuming it only when it is necessary to change the contents of the electronic price display unit. There is a need to implement a technology that can be used.

The present invention has been proposed in view of the above points, and an object of the present invention is when there is a need to change the contents of the electronic price display unit after harvesting a current of tens of microns during the turn-on time of an indoor etc. used in a store. It is intended to provide an indoor light energy harvesting-based electronic price display device that can temporarily use the harvested power source.

In addition, it is an object of the present invention to temporarily use the harvested power source only when it is necessary to change the contents of the electronic price display unit after harvesting a current of several tens of microns during the turn-on time of the indoor light used in the store. It is possible to provide an indoor light energy harvesting-based electronic price display device capable of using a test battery to change the contents of the electronic price display unit after installation of the device.

In addition, an object of the present invention is to provide an indoor light energy harvesting-based electronic price display device capable of preventing leakage of power already harvested after the indoor light is turned off.

In order to achieve the above object, the present invention includes a housing 100, an electronic price display unit 200 disposed on one surface of the housing to display price information in the form of e-paper, and an electronic price display unit so that the electronic price display unit converts. Indoor light energy harvesting including a power supply unit 300 for supplying power to an electronic price display unit and an ESL control unit 400 for controlling the change of information displayed on the electronic price display unit according to the identification of a content change manipulation event for the electronic price display unit As a base electronic price display device, the power supply unit 300, a solar cell member 310 for generating a current from indoor light energy; A super capacitor member 320 that stores electricity through a current generated from the solar cell member; A charging member 330 consisting of a circuit diagram connecting the solar cell member and the super capacitor member and for storing electric current by flowing the current generated from the solar cell member through the super capacitor member; A power control member 340 that is connected to the charging member so as to be energized and controls the supply of power from the super capacitor member to the electronic price display unit.

Further, the power supply unit 300 may include a battery accommodating member 361 connected to the charging member and interfacing to provide power supplied from the test battery to the electronic price display unit connected to the charging member; A Zener diode member (362) mounted between the battery receiving member and the charging member and interfacing to provide power from the test battery through the battery receiving member to the electronic price display unit as a diode that directs current flow from the battery receiving member to the charging member. ); may be further provided.

In addition, the power supply unit 300 is mounted on the charging member and enables current flow between the super capacitor member and the charging member according to its switching on, and blocks the current flow between the super capacitor member and the charging member according to its switching off. At least one capacitor switch member 371, 372; A voltage detection member 373 for sensing a potential from the solar cell member while being connected to the charging member corresponding to the (+) terminal of the solar cell member; When the voltage detection member is connected to the voltage detection member and the charging member, the detection result of the voltage detection member is monitored, and when the voltage detection member's (+) terminal side potential is below the threshold, the capacitor switch member is switched off and the super capacitor member When the voltage detection member is monitored and the potential of the positive terminal of the solar cell member is above the threshold, the capacitor switch member is switched on to maintain the current flow from the cell member to the super capacitor member. The leakage current blocking control member 374 to be; may be further provided.

The present invention is provided with a power supply unit including a solar cell member, a super capacitor member, a charging member, and a power control member, thus harvesting micro current generated from the interior of the store while the interior of the store is turned on without a separate coin battery. It shows the advantage of being able to use it as an energy source when a content change manipulation event occurs in the electronic price display unit afterwards.

In addition, according to the present invention, the harvested power can be temporarily used only when it is necessary to change the contents of the electronic price display unit after harvesting a current of several tens of microns during the time when the indoor light used in the store is turned on. As a separate battery accommodating member is provided, it is possible to use a test battery to change the contents of the electronic price display unit even before the super capacitor is charged after installation of the device.

In addition, the present invention includes a voltage detection member, a leakage current blocking control member, and at least one capacitor switch member, so that the power harvested to the super capacitor leaks when no current from the solar cell member is generated when the room is turned off. It shows the advantage of being able to prevent it from becoming.

[Fig. 1] is an exemplary view showing the state of use of a general electronic price display device,
[Figure 2] is a block diagram of an electronic price display device according to the prior art,
3 is a block diagram of an electronic price display device based on indoor light energy harvesting according to the present invention,
[Fig. 4] is an exemplary view schematically showing a power supply unit according to a first embodiment of the present invention;
[Fig. 5] is an exemplary view schematically showing a power supply unit according to a second embodiment of the present invention;
6 is an exemplary view schematically showing a power supply unit according to a third embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

[Fig. 4] is an exemplary view schematically showing a power supply unit according to a first embodiment of the present invention.

Referring to FIG. 4, first, the present invention may include a housing 100, an electronic price display unit 200, a power supply unit 300, and an ESL control unit 400.

The housing 100 may mount the electronic price display unit 200, the power supply unit 300, and the ESL control unit 400 on the inner or outer surface thereof, and preferably, the solar of the power supply unit 300 on the upper surface thereof. The cell member 310 may be disposed and the electronic price display unit 200 may be disposed in front of the cell member 310.

The electronic price display unit 200 may be disposed on one surface of the housing 100 and configured to display price information in the form of an e-paper as shown in FIG. 1. In addition, the electronic price display unit 200 may display specification information or price information of a corresponding product on its own due to the characteristics of the e-paper without supplying power from the outside.

Here, the electronic price display unit 200 must provide a separate energy source from the outside in order to change the specification information or price information displayed by the electronic price display unit 200 according to user manipulation.

To this end, a separate coin battery has been conventionally employed, but in order to overcome the problem of employing the coin battery, the present invention excludes the existing coin battery and has a power supply unit 300.

That is, the power supply unit 300 is driven according to the control operation of the ESL control unit 400 when there is a content change manipulation event in the electronic price display unit 200 according to a user manipulation, and the power required to perform the content change manipulation. Supply.

When the electronic price display unit 200 identifies a content change manipulation event by the user, the ESL control unit 400 controls the driving of the power supply unit 300 to supply power to the electronic price display unit 200 and manipulates the user. Controls change of display information of the electronic price display unit 200 according to the following.

Meanwhile, according to the first embodiment of the present invention, the power supply unit 300 includes a solar cell member 310, a super capacitor member 320, a charging member 330, a power control member 340, and an output member 350. Can be equipped.

The solar cell member 310 may be preferably disposed on the upper surface of the housing 100 and is connected to the super capacitor member 320 through a circuit diagram of the charging member 330 as shown in FIG. As the current is generated from the supercapacitor member 320, power is stored,

The super capacitor member 320 is connected to the solar cell member 310 through a circuit diagram of the charging member 330 as shown in FIG. 4 and stores electricity through current generated from the solar cell member 310.

In this way, the power stored in the super capacitor member 320 may be provided to the electronic price display unit 200 under the control of the ESL control unit 400, from the super capacitor member 320 to the electronic price display unit 200. Direct control of the supply of power may be performed by the power control member 340 connected to the charging member 330 and a circuit diagram as shown in FIG. 4.

The charging member 330 is made of a circuit diagram connecting the super capacitor member 320 and one or more solar cell members 310 as shown in [Fig. 4] and transmits the current generated from the solar cell member 310 to the super capacitor member ( Current generated from the solar cell member 310 is energized to the super capacitor member 320 so that electricity can be stored in the cell 320.

Here, as a specific embodiment of the charging member 330, a circuit diagram in which elements such as a plurality of resistance elements, a comparator 332, a Zener diode 333, and a power MOSFET 334 are combined as shown in [Fig. 4] Can be.

The power control member 340 is electrically connected to the charging member 330 and controls power supply from the super capacitor member 320 to the electronic price display unit 200 as shown in FIG. 4.

That is, the power supply unit 300 is driven according to the control operation of the ESL control unit 400 when there is a content change manipulation event in the electronic price display unit 200 according to a user manipulation, and the power required to perform the content change manipulation. Supply.

For example, when a content change manipulation event by a user in the electronic price display unit 200 is identified by the ESL control unit 400, the ESL control unit 400 controls the power control member 340 to control the power control member 340. The supercapacitor member 320 is directly controlled so that the stored power from the supercapacitor member 320 is supplied to the electronic price display unit 200.

When the electronic price display unit 200 identifies a content change manipulation event by the user, the ESL control unit 400 controls the driving of the power supply unit 300 to supply power to the electronic price display unit 200 and manipulates the user. Controls change of display information of the electronic price display unit 200 according to the following.

The output member 350 is a terminal member of the charging member 330 to which power from the super capacitor member 320 is externally provided as shown in [Fig. 4], and the electronic price display unit 200 is connected thereto.

[Fig. 5] is an exemplary view schematically showing a power supply unit according to a second embodiment of the present invention.

Referring to FIG. 5, the power supply unit 300 according to the second embodiment of the present invention may further include a battery accommodating member 361 and a Zener diode member 362.

The battery accommodating member 361 is connected to the charging member 330, which is a circuit diagram, as shown in Fig. 5, and the power supplied from the small test battery fitted therein is an output member that is a terminal member of the charging member 330 ( The interface is provided to the electronic price display unit 200 connected to 350).

For example, it is necessary to test whether the operation can be performed properly immediately after the electronic price display device based on indoor light energy harvesting according to the present invention is installed. In this case, before the micro current is still harvested in the super capacitor member 320 Therefore, even when a content change manipulation event occurs in the electronic price display unit 200, it is difficult to supply an energy source corresponding thereto.

In this way, by providing the battery accommodating member 361 in which a small test battery can be employed in the charging member 330, which is the circuit diagram in FIG. 5, it was seen even before the micro current was harvested in the super capacitor member 320. The electronic price display device according to the second embodiment of the present invention can be tested.

The Zener diode member 362 may be mounted on a patterning portion connecting the battery accommodating member 361 and the charging member 330 as shown in [Fig. 5], and power from the test battery through the battery accommodating member 361 The interface is provided to the electronic price display unit 200.

Here, after the power from the small test battery is supplied to the electronic price display unit 200 through the battery accommodating member 361, energy must be harvested from the solar cell member 310.

That is, the current generated from the solar cell member 310 must be stored in the super capacitor member 320 through the charging member 330 circuit in [Fig. 5]. In this process, the current from the solar cell member 310 The flow toward the battery accommodating member 361 may be blocked by the Zener diode member 362.

In this way, as the Zener diode member 362 is provided as shown in [Fig. 5], an interface so that power from the test battery through the battery accommodating member 361 can be smoothly provided to the electronic price display unit 200 is provided, and the solar cell The current generated from the member 310 can be stored in the super capacitor member 320 without leaking toward the battery accommodating member 361.

6 is an exemplary view schematically showing a power supply unit according to a third embodiment of the present invention.

6, the power supply unit 300 according to the third embodiment of the present invention includes one or more capacitor switch members 371 and 372, a voltage detection member 373, and a leakage current blocking control member 374. Can be equipped.

One or more capacitor switch members 371 and 372 may be mounted on the charging member 330 as shown in [Fig. 6], and current flow between the super capacitor member 320 and the charging member 330 is controlled according to their switching on. It enables and blocks the current flow between the super capacitor member 320 and the charging member 330 according to their switching off.

Specifically, when the indoor light is turned off due to the end of the store's business, no more micro-current is generated from the solar cell member 310. At this time, the power harvested to the super capacitor member 320 is transferred to the charging member 330. Since leakage occurs in the circuit, it is necessary to block it.

In this way, as a method for preventing the power harvested in the super capacitor member 320 from leaking through the circuit elements of the charging member 330, the supercapacitor member 320 and the part forming a closed circuit are shown in Fig. 6 As shown in ], when the capacitor switch member 371 is switched off after the capacitor switch member 371 is provided, the leakage current flowing from the super capacitor member 320 to the closed network of the charging member 330 can be blocked. .

In addition, a capacitor switch member 372 is provided as shown in [Fig. 6] in the current supply bridge portion from the super capacitor member 320 to the comparator 332 element, which is a component of the charging member 330, and then the capacitor switch When the member 372 is switched off, a leakage current flowing from the supercapacitor member 320 to the comparator 332 of the charging member 300 can be blocked.

Here, an important issue is the question of when to switch off each of the capacitor switch members 371 and 372. To this end, in the third embodiment of the present invention, a voltage detection member 373 is provided.

That is, the voltage detection member 373 detects a potential from the solar cell member 310 in a state connected to the circuit of the charging member 330 corresponding to the (+) terminal of the solar cell member as shown in [Fig. 6]. .

At this time, the leakage current blocking control member 374 monitors the detection result of the voltage detection member 373 while being connected to the voltage detection member 373 and the charging member 330, and the monitoring result of the voltage detection member 373, solar When the potential of the cell member 310 toward the (+) terminal is less than or equal to the threshold value, the capacitor switch members 371 and 372 are switched off to block leakage current from the supercapacitor member 320.

That is, as a result of monitoring the voltage detection member 373, when the potential toward the (+) terminal of the solar cell member 310 is less than or equal to the threshold, the store's business was terminated and all the interiors of the store were turned off. Since micro current is not generated from ), it can be seen that the potential toward the (+) terminal of the solar cell member 310 represents a threshold value or less.

Of course, as a result of monitoring the voltage detection member 373, when the potential toward the (+) terminal of the solar cell member 310 exceeds the threshold value, the indoor, etc. is turned on to continuously generate a micro current from the solar cell member 310. In this state, the capacitor switch members 371 and 372 must maintain the switching on state.

That is, as a result of monitoring of the voltage detection member 373, the leakage current blocking control member 374 switches on the capacitor switch members 371 and 372 when the potential toward the (+) terminal of the solar cell member 310 is greater than or equal to the threshold value. Current flow from the solar cell member 310 to the super capacitor member 320 is maintained.

100: housing
200: electronic price display unit
300: power supply
310: no solar cell
320: super capacitor member
330: filling member
340: absence of power control
361: battery accommodating member
362: Zener diode member
371, 372: absence of a capacitor switch
373: voltage detection member
374: Leakage current blocking control member
400: ESL control unit

Claims (3)

The housing 100, an electronic price display unit 200 disposed on one surface of the housing to display price information in the form of e-paper, and a power supply unit supplying power to the electronic price display unit so that the electronic price display unit performs a conversion operation. Indoor light energy harvesting-based electronic price display including 300 and an ESL control unit 400 for controlling the change of information displayed on the electronic price display unit according to the identification of a content change manipulation event for the electronic price display unit As a device,
The power supply unit 300,
A solar cell member 310 generating an electric current from indoor light energy;
A super capacitor member 320 that stores electricity through current generated from the solar cell member;
A charging member (330) made of a circuit diagram connecting the solar cell member and the super capacitor member and configured to store current by flowing the current generated from the solar cell member through the super capacitor member;
A power control member 340 that is electrically connected to the charging member and controls supply of power from the super capacitor member to the electronic price display unit;
Electronic price display device based on indoor light energy harvesting, characterized in that it comprises a.
The method according to claim 1,
The power supply unit 300,
A battery accommodating member 361 connected to the charging member and interfacing to provide power supplied from a test battery to the electronic price display unit connected to the charging member;
A diode mounted between the battery accommodating member and the charging member and directing current flow from the battery accommodating member toward the charging member, and an interface to provide power from the test battery through the battery accommodating member to the electronic price display unit A Zener diode member 362;
Electronic price display device based on indoor light energy harvesting, characterized in that it further comprises.
The method according to claim 2,
The power supply unit 300,
One or more capacitors mounted on the charging member to enable current flow between the super capacitor member and the charging member according to their switching on and to block current flow between the super capacitor member and the charging member according to their switching off Switch members 371 and 372;
A voltage detection member 373 for sensing a potential from the solar cell member while being connected to the charging member corresponding to the (+) terminal of the solar cell member;
Monitoring the detection result of the voltage detection member while being connected to the voltage detection member and the charging member, and when the monitoring result of the voltage detection member, the potential of the (+) terminal side of the solar cell member is less than or equal to a threshold value, the capacitor switch member is Switching off to block leakage current flow from the super capacitor member, and as a result of monitoring of the voltage detection member, when the potential toward the (+) terminal of the solar cell member is greater than or equal to a threshold value, the capacitor switch member is switched on to turn on the solar cell. A leakage current blocking control member 374 for maintaining current flow from the member to the super capacitor member;
Electronic price display device based on indoor light energy harvesting, characterized in that it further comprises.

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