KR200423897Y1 - Storage battery for floating light - Google Patents

Abstract

The present invention relates to a battery for back buoys. In particular, a positive electrode plate and a negative electrode plate, which are alloys of lead and antimony, are arranged in sequence through spacers and insulating plates in an inner space of a container made of FRP. By connecting the protruding portion of the pole plate to the terminal through the connecting piece, the electrical coupling state is prevented from being damaged even if the container is shaken. Also, the protruding portion is firmly coupled to the connecting piece by welding so that the charging current is increased. The present invention relates to a buoy battery such as to enable a relatively large capacity of 5 to 40 A.

Therefore, according to the back buoy battery of the present invention, a positive electrode plate and a negative electrode plate, which are alloys of lead and antimony, are arranged in this order while placing an insulating plate between the interior spaces of a container made of FRP material. The protrusions formed at the ends of the ends are coupled to terminals exposed to the outside through connecting pieces, respectively, and stably supported by spacers and insulating plates sandwiched between both inner sides of the container and the pole plates, thereby being prevented by waves or wind. In order to prevent the electrical coupling state from being damaged even if the container is shaken together with the floating route display device, the protrusions of the electrode plates are joined to the connecting pieces by welding, and the material is made of an alloy of lead and antimony. Since the charging current is relatively large, it can be used with a capacity of 5 to 40A, and the time for recharging is reduced when over discharged It will be effective.

Terminals, solar cells, light emitting lamps, pole plates, connecting pieces, sealing layers, containers, etc.

Description

Storage battery for floating buoys {Storage battery for floating light}

1 is a schematic view showing the internal configuration of a conventional storage battery.

2 is a cross-sectional view showing the configuration of the storage battery of the present invention.

Figure 3 is a partial perspective view showing the internal configuration of the storage battery,

4 is a perspective view showing a state of use of the present invention,

Explanation of symbols on the main parts of the drawings

1: container 2: container

3: Insulation plate 4: Positive electrode plate

5, 9: protrusions 6, 10: connecting piece

7, 11: terminal 8: negative pole plate

15 spacer 16 sealing layer

The present invention relates to a battery for back buoys. In particular, a positive electrode plate and a negative electrode plate, which are alloys of lead and antimony, are arranged in sequence through spacers and insulating plates in an inner space of a container made of FRP. By connecting the protruding part of the pole plate to the terminal through the connecting piece, it prevents the electrical coupling state from being damaged even if the container is shaken. In addition, the protruding part is firmly coupled to the connecting piece by welding so that the charging current It relates to a buoy battery, such that is possible even with a relatively large capacity of 5-40A.

Applicant calls this buoy accumulator LDA-270.

Generally, there are two types of route markers for guiding a ship sailing the sea, and it is well known that a lighthouse or a buoy serves as a route marker.

And since the fixed route marking device is fixedly installed on the seabed, it is suitable as the route marking device because there is no change due to the difference between tides, but it is not suitable to be installed in the deep sea area.

In addition, the floating route markers have a low installation cost and have a low resistance to external forces due to floating, which is a mechanically advantageous structure.

However, in the sea area where there are many reefs or waves that cannot be fixedly installed, the floating method is used to connect them while fixing them to the floor with chains.

In this case, a method of installing a solar cell and charging and discharging a power source generated by solar light to discharge the battery is widely used.

Storage batteries, which are widely used as a general energy source in modern society, are also called secondary batteries because they reversibly react as a battery capable of repeating charging and discharging reactions.

Lead and alkaline batteries are used, but lead batteries are commonly used. It consists of a reversible positive and negative electrode active material plate, electrolyte, electrolytic cell, separator (separator), and uses the change of electrolytic energy when the positive and negative electrode active materials cause chemical reaction with electrolyte.

The phenomenon that draws current from the anode to the cathode by connecting the positive and negative electrodes is called discharge. Charging is the process of storing electrical energy as chemical energy by causing a chemical reaction to flow the current from the outside to the reverse direction.

In addition, the storage battery used in the above-mentioned floating route labeling device must not be introduced with foreign substances such as water or dust from the outside, but also stable charging and discharging must be performed.

In the related art, as shown in FIG. 1, two positive (positive) pole plates 102 are sandwiched by sandwiching an insulating plate in a sealed container 101 made of an iron enclosure and an ebonite enclosure as shown in FIG. 1. In the state where three negative pole plates 104 are arranged, they are connected to the connecting pieces 103 and 105, respectively, and then connected to terminals that are partially exposed to the outside. To the lamp.

However, the storage battery installed in the above-mentioned conventional floating route marking device is severely shaken by the waves, and as a result, the portions joined by welding with the pole plates 102 and 104 and the connecting pieces 103 and 105 are damaged. There was a problem that occurs frequently.

In addition, moisture or dirt gets into the solar cells, which often prevents the smooth charging. As a result, overdischarge occurs in the accumulators. Accordingly, the operation of collecting and forcibly recharging the accumulators is performed. It should be done periodically.

However, since five pole plates 102 and 104 are formed, the current density is low, and the bond between the pole plates 102 and 104 and the connecting pieces 103 and 105 is very small. Since the material of (104) is made of pure lead, the charging current is low, so the charging time becomes very long, and accordingly, there is a problem of having to prepare a spare battery for embroidery.

The present invention, which solves the above problems, is devised to solve the above problems, and is a positive electrode plate that is an alloy of lead and antimony while interposing a spacer and an insulating plate in an inner space of a container made of FRP material. By arranging the negative and negative plates in turn and connecting them to the terminals through the connecting pieces to which the protrusions of these plates are connected, the electrical coupling state is prevented from being damaged even if the container is shaken. It is intended to provide a buoy battery such that it is relatively tightly coupled by welding to enable a capacity of 5 to 40 A with a relatively large charging current.

Therefore, the present invention is to fill the internal space of the container connected to the solar cell and the light-emitting lamp by the bolting method to the terminal to replenish through the refilling port while filling the filling liquid, buoy storage battery, in the space inside the container Arrange the four positive pole plates and the five negative pole plates in turn while sandwiching the insulating plate, and connect them to the terminals while connecting the end protrusions of the positive pole plates with the connecting pieces, and connect the connecting pieces to the end protrusions of the negative pole plates. It is to provide a storage battery for buoys to be connected to the terminal while being coupled, and to form an airtight layer with a sealing compound in the upper opening of the container with spacers on both sides of the pole plate.

In addition, the present invention, while the container is made of FRP while the pole plate is to provide a storage battery for buoys such as to be made of an alloy of lead and antimony.

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

That is, the configuration and operation of the present inventors model name LDA-270 will be described in detail with the drawings.

2 and 3 show the configuration according to an embodiment of the present invention, the amount of the alloy of lead and antimony while sandwiching the insulating plate 3 in the internal space (2) of the container 1 of the FRP material (+ 4 pole plates 4) and 5 negative pole plates 8 are arranged in this order, and the protruding portions 5 of the positive pole plates 4 are connected to each other by a connecting piece 6. It is connected to the terminal 7 which is partially exposed to the outside.

In addition, the end protrusion 9 of the negative pole plate 8 is connected to a terminal 11 which is partially exposed to the outside in a state of being coupled with the connecting piece 10, and the terminals 7 and 11 described above. Is connected to the solar cell 12 and the light emitting lamp 13 by the bolt fastening method.

In addition, while filling the space 2 of the container 1 with the filling liquid, the filling liquid 14 is replenished through the filling port 14, and the spacers 15 are internally installed on both sides of the inside of the container 1. The electrode plates 4 and 8 are prevented from swinging arbitrarily.

In addition, the upper opening of the container 1 is configured to form a sealing layer 16 with a sealing compound (pitch).

On the other hand, Figure 4 shows the installation state of the present invention, the other side of the chain 22 is fixed to the bottom of one side fixed to the bottom of the floating route display device main body 21 so as not to move randomly in the wave, The solar cell 12 is installed on the upper surface of the main body 21 in which the battery container 1 is installed to be charged using the light and heat of the sun shining during the day.

The light emitting lamp 13 is installed on the support 23 above the floating route display device main body 21.

The solar cell 12 is mounted on the upper surface of the floating route display device main body 21 which is fixed to the bottom through the chain 22 at the bottom of the main body so as not to move randomly even in the waves. By installing it to be charged using the light and heat of the sun shining in the daytime, and to install the light emitting lamp 13 on the support 23 upwards to illuminate the surroundings,

A plurality of accumulators installed inside the floating route display device main body 21 charges the power through the solar cell 12 during the day and discharges the light at night while lighting the light emitting lamp 13 to illuminate the surroundings. But

The battery includes a positive electrode plate 4 having four positive (4) alloys of lead and antimony, while sandwiching the insulating plate 3 in the space 2 inside the container 1 made of FRP material having high heat resistance and cold resistance. By arranging the five negative pole plates 8 in sequence, the current density becomes good due to the total of nine pole plates 4 and 8.

In addition, the protrusion 5 formed at the end of the positive electrode plate 4 is tightly coupled to the connecting piece 6 by welding to expose a part through the terminal 7 to the outside.

Through a relatively wide protrusion 9 formed at the end of the negative pole plate 8 by welding to the connecting piece 10 to be firmly coupled to expose a portion through the terminal 11 to the outside by the flow Do not worry about damage.

In such a state, the upper end of the container 1 is exposed to a portion of the terminal 7, 11 and the supplementary port 14, and the sealing layer 16 is formed with a sealing compound (pitch), thereby providing the The filling liquid filled in the inner space 2 is not exposed to the outside, and the filling liquid 14 can be replenished with the filling liquid 14.

The inner space of the container 1 together with the insulating plate 3 interposed between the pole plates 4 and 8 made of an alloy of lead and antimony by internally installing spacers 15 on both sides of the inside of the container 1. In (2), the positive electrode plate 4 and the negative electrode plate 8 are stably supported so that the vessel 1, together with the floating route indicator, may be electrically driven by waves or wind. To prevent damage to the coupling state.

When the terminals 7 and 11 are connected to the solar cell 12 and the light emitting lamp 13 by a bolting method, the terminals 7 and 11 can be used safely in a free state of charge and discharge.

In addition, a relatively wide portion of the protrusion 5 of the positive electrode plate 4 and the protrusion 9 of the negative electrode plate 8 to the connecting pieces 6 and 10 is firmly coupled by welding. While the material is made of an alloy of lead and antimony, the charging current is possible with a capacity of 5 to 40 A, which is much larger than that of the conventional 1 A, thereby reducing the time required for recharging when overdischarged.

Table 1 below compares the specifications of the conventional conventional storage battery and the storage battery according to the present invention.

As described above, according to the back buoy battery of the present invention, a positive electrode plate and a negative electrode plate, which are alloys of lead and antimony, are arranged in order while an insulating plate is interposed in a space inside an FRP container. The protrusions formed at the ends of these pole plates are coupled to terminals exposed to the outside through connecting pieces, respectively, and stably supported by spacers and insulating plates sandwiched between both inner sides of the container and the pole plates. However, even if the container is shaken with the floating route display device by the wind, the electrical coupling state is prevented from being damaged. The protrusions of the electrode plates are joined to the connecting pieces by welding, and the material is alloy of lead and antimony. Because it is manufactured in the state of charge, it is possible to have a capacity of 5 ~ 40A with a relatively high charging current. The effect is less time.

In addition, LDA-270, the storage battery of the present invention, has a smaller capacity, smaller size and thickness than the existing product, and at least the effect of the number of pole plates is more than that of the existing product.

In addition, the present invention is easy to transport, transport and installation in light weight as the volume and thickness and size of the less electrolyte is injected.

Claims (2)

The refill port 14 is provided while the filling liquid is filled in the internal space 2 of the container 1 connected to the solar cell 12 and the light emitting lamp 13 by bolting method to the terminals 7 and 11. In the battery for buoys, etc., Four positive electrode plates 4 and five negative electrode plates 8 are arranged in this order while sandwiching the insulating plate 3 in the space 2 inside the container 1, The end projection 5 of the positive pole plate 4 is connected to the terminal 7 while engaging with the connecting piece 6, The end projection 9 of the negative pole plate 8 is connected to the terminal 11 while being coupled with the connecting piece 10. A storage battery for a buoy, etc., characterized in that a sealing layer (16) is formed at a top opening of the container (1) in which spacers (15) are provided on both sides of the pole plate (4) (8). The method of claim 1, Said container 1 is made of FRP, while the pole plates 4 and 8 are made of an alloy of lead and antimony.

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