KR200494944Y1 - Rubber cone - Google Patents

Abstract

Lavacon is initiated. The disclosed rubber cone is supported in contact with the ground, and is made in the form of a square plate, the body part including a base part having an inclined surface on the side and a cone part integrally extending from the base part to the upper part; A plurality of LED lights installed at equal intervals along the upper outer peripheral surface of the cone to emit light to the outside; a solar panel installed on the inclined surface to convert solar energy into electrical energy to generate electricity; a battery installed inside the main body and charged with electricity generated from the solar panel, and the charged electricity is used for the plurality of LEDs; an illuminance sensor installed in the main body to measure illuminance and output the measured illuminance to the control unit; It is installed inside the base part, charges the battery with electricity generated from the solar panel, supplies power of the battery to the plurality of LEDs to control the operation of the plurality of LEDs, and receives from the illuminance sensor and a control unit controlling to turn on the plurality of LED lights when the measured illuminance is less than or equal to a preset value.

Description

Rabacon {RUBBER CONE}

The present invention relates to a rubber cone, and more particularly, to a rubber cone that can be easily identified at night or when fog occurs due to the light emission of the LED lamp composed of an LED lamp.

In general, rubber cones are also called traffic cones, safety cones, color cones, etc., and are used for the purpose of vehicle control or partial traffic control and pedestrian safety. That is, it is used so that the driver can easily identify and recognize the lane change situation when the road is narrowed or the road is bent due to road construction, etc. or pedestrians can pass safely.

This conventional rubber cone is composed of a base part in contact with the support surface, and a cone-shaped cone part protruding from the base to the upper part. These rubber cones are made of a synthetic resin material such as rubber or plastic.

Some of these rubber cones have reflective paper attached to the cone, but their discrimination is not satisfactory enough, so even if they are installed on construction sites, there is a problem that vehicle drivers or pedestrians cannot easily recognize them. Because of the shape, when the reflective paper is contaminated, there is a problem such as greatly reduced discrimination.

In order to solve this problem, the Lavacon with lamps such as LEDs in the Lavacon so that the driver or pedestrian can clearly identify the Lavacon by the light emission of the lamp. Registered Patent No. 10-1003401, Registered Utility Model 20-0484189 No., the registered utility model No. 20-0223955, etc. have been proposed.

However, the rubber cone composed of lamps such as LEDs is structurally very complicated, and only the power supply through the battery is presented, and it is inconvenient to use because it is cumbersome to periodically replace the battery.

In addition, in Patent Registration No. 10-1003401, the LED lamp is installed in the inner center of the cone, and in Utility Model Registration No. 20-0484189, the LED lamp is installed inside the floor base, and light is emitted from the LED lamp because light is emitted inside the rubber cone. The light was not visible from the outside, so the discrimination was not high enough to be satisfactory.

In addition, Utility Model Registration No. 20-0223955 uses a small light bulb instead of an LED lamp, and has a configuration in which small light bulbs are arranged in the form of an arrow on the outside of the cone, but the electronic components such as switches and timers are configured at the top of the cone. It was very vulnerable to rainwater, so there was a problem that it was easily broken.

Registered Patent No. 10-1884461 Registered Patent No. 10-1003401 Registered Utility Model No. 20-0484189 Registered Utility Model No. 20-0223955

The present invention has been devised to solve the problems of the prior art as described above, and it is an improved form so that it can be used conveniently without replacing the battery by generating electricity through solar energy while improving visibility by configuring an LED light module without configuring a half ring An object of the present invention is to provide a rubber cone having a

However, the purpose of the present invention is not limited thereto, and even if not explicitly mentioned, the purpose or effect that can be grasped from the solution or embodiment of the problem is also included therein.

The rubber cone of the present invention for achieving the above object is supported in contact with the ground, is made in the form of a square plate, and is widened toward the lower part and is formed in a cone shape integrally extending from the base part to the upper part and the base part having an inclined surface on the side surface. a body portion including a cone portion; A plurality of LED lights installed at equal intervals along the upper outer peripheral surface of the cone to emit light to the outside; a solar panel installed on the inclined surface to convert solar energy into electrical energy to generate electricity; a battery installed inside the main body, the electricity generated from the solar panel is charged, and the charged electricity is used for the plurality of LEDs; an illuminance sensor installed in the main body to measure illuminance and output the measured illuminance to the control unit; It is installed inside the base part, charges the battery with electricity generated from the solar panel, supplies power of the battery to the plurality of LEDs to control the operation of the plurality of LEDs, and receives from the illuminance sensor and a control unit controlling to turn on the plurality of LED lights when the measured illuminance is less than or equal to a preset value.

A side of the base part may be electrically connected to the controller and may include a charging jack for charging the battery.

Each of the plurality of LED lights may be installed on the outer surface of the cone part, and may be configured to be installed to protrude from the outer surface of the cone part or to be installed in a form embedded in the cone part.

It may be configured to further include; a slide-type solar panel that is drawn into the base part through a slit hole formed on the side of the base part or drawn out laterally from the base part to charge the battery.

According to the above, the present invention is a form in which the visibility of the rubber cone to vehicle drivers or pedestrians can be greatly improved because the LED lamp is configured in the rubber cone, and it is used as a power source for the LED lamp by generating electricity using solar energy and charging it in a battery By doing so, the power supply is easy and there is an effect that it can be used continuously without the need for replacement of the battery. The battery can be easily charged through the charging jack so that stable operation of the rubber cone can be achieved.

In addition, in the present invention, the LED lights are installed at equal intervals on the upper outer peripheral surface of the rubber cone, and the visibility is improved compared to the existing rubber cone, thereby increasing the prevention efficiency of safety accidents.

1 is a perspective view showing a rubber cone according to a first embodiment of the present invention,
Figure 2 is a front view of the rubber cone of the present invention,
3 is a plan view of the rubber cone of the present invention,
Figure 4 is a bottom view of the rubber cone of the present invention,
5 is a block diagram showing the control state of the rubber cone of the present invention,
6 is a perspective view showing a rubber cone according to a second embodiment of the present invention,
7 is a view for explaining the configuration and operating state of the linear actuator for driving the slide-type solar panel of FIG.
8 is a view showing the upper internal structure of the rubber cone according to the third embodiment of the present invention,
Figure 9 is a view showing the configuration of the rotational driving unit for the reciprocating rotational movement of the rubber cone according to the third embodiment of the present invention.

Objects, features and advantages of the present invention will be easily understood through the following preferred embodiments in conjunction with the accompanying drawings. However, it will be understood by those skilled in the art that the present invention is not limited to the embodiments described herein and may be embodied in other forms through the examples described below.

In describing the specific embodiments below, a number of specific contents have been written to more specifically describe the design and help understanding. In addition, it is mentioned in advance that parts that are commonly known in describing the design and not largely related to the design are not described in order to prevent confusion in explaining the present invention.

Hereinafter, the lavacon 10 according to the first embodiment of the present invention will be described in detail.

The rubber cone 10 of the present invention is configured to include a main body 101 , an LED lamp 110 , a solar panel 112 , a battery 114 , and a control unit 120 .

The body portion 101 is configured to include a base portion 102 in the form of a square plate, and a cone portion 103 integrally protruding from the center of the upper surface of the base portion 102 to the upper portion. In the present invention, the upper end of the cone 103 may be in an open form, or may be in a closed form as shown in the drawings.

The main body 101 may be made of a synthetic resin material such as rubber or plastic, and in particular, the main body 101 of the present invention may be made of a soft silicone material.

In addition, the body portion 101 of the present invention can be configured to have a luminous function by mixing a luminous component with a silicon raw material during manufacture and made of a silicone material containing a luminous component.

On the other hand, the base portion 102 is made in the form of a square plate, and is made in the shape of a lower beam that increases in size from the upper part to the lower part, and the side of the base part 102 is configured such that an inclined surface 102a is formed.

In the present invention, since the solar panel 112 is installed on the inclined surface 102a, the solar power generation efficiency can be improved compared to the vertical side.

The LED lamp 110 is a lighting module equipped with an LED, and is configured in plurality to be installed at equal intervals on the upper outer surface of the cone unit 103 . The LED lamp 110 may be installed on the outer surface of the cone part 103 in the vertical direction, and may be installed to protrude from the outer surface of the cone part 103 or installed in a form that is hooked into the cone part 103 .

The solar panel 112 is composed of a solar cell that converts solar energy into electrical energy to generate electricity, and is configured to be installed on the inclined side of the base unit 102 .

The battery 114 is installed inside the base unit 102 and is charged with electricity generated from the solar panel 112 , and the charged electricity is configured to be used as a power source for the LED lamp 110 .

The control unit 120 is installed inside the base unit 102 so as to be adjacent to the battery 114 , and is configured to include a charging control unit 121 and an LED control unit 122 .

The charging control unit 121 is electrically connected to the solar panel 112 and the battery 114 to charge electricity generated from the solar panel 112 to the battery 114, and the LED control unit 122 is the battery ( 114) and the LED lamp 110 are electrically connected to apply the power of the battery 114 to the LED lamp 110 to control the operation of the LED lamp 110. The LED control unit 122 may turn on (light on) or off (turn off) the LED lamp 110, and may control the LED lamp 110 to blink.

In the present invention, a power line (w) electrically connecting the control unit 120 and the battery 114 so that the control unit 120 applies the power of the battery 114 to the LED light 110 is configured, and this power line ( w) is installed in a vertical direction along the cone part (w) and may be installed to be embedded in the outer surface of the cone part (w), or may be vertically fixedly installed on the inner surface of the cone part (w).

In the present invention having the above configuration, a plurality of LED lights 110 are configured at equal intervals on the upper outer circumferential surface of the cone part 103. Pedestrians can more easily and reliably recognize the Lavacon, so visibility is greatly improved and accidents can be prevented.

In addition, in the present invention, the battery 114 is charged through the solar panel 112, not the method of replacing the battery, and the battery 114 is continuously charged while supplying power to the LED lamp 110. Because this is done, the management of the rubber cone is very convenient, and the configuration of the battery 114 and the control unit 120 is installed inside the base unit 102, so that it does not directly hit rainwater, etc., so that electrical stability can be secured. have.

In particular, in the present invention, the side surface of the base unit 102 is formed in an inclined form, and the solar panel 112 is installed on the inclined side surface 102a, whereby good power generation of the solar panel 112 can be achieved.

Meanwhile, in the present invention, the illuminance sensor 124 may be installed on the upper surface of the base 110 . The illuminance sensor 124 is configured to measure the illuminance and output the measured illuminance to the controller 120 . In the drawing, the illuminance sensor 124 is installed on the upper surface of the base unit 102, but is not limited thereto, and the illuminance sensor 124 may be installed on one side of the side of the base unit 102, and It may be installed on one side of the outer circumferential surface. That is, the illuminance sensor 124 may measure the illuminance of the external environment, and may be installed anywhere on the outer surface of the main body 101 .

When the measured illuminance received from the illuminance sensor 124 is equal to or less than a preset illuminance, the controller 120 may control the LED lamp 110 to turn on.

That is, the present invention detects a dark environment (in low light) such as at night and fog through the illuminance sensor 124 so that the LED light 110 is turned on, so that automatic lighting is performed according to the illuminance without using a separate switch. Convenience of use can be greatly improved.

6 and 7, the rubber cone 10 according to the second embodiment of the present invention is a slide-type solar panel installed to be drawn in or withdrawn through the slit hole 105 formed on the side surface of the base portion 102 ( 130) may be configured to further include.

A pair of guide rails 132 are configured side by side on both inner sides of the base unit 102 , and the slide-type solar panel 130 is installed between the pair of guide rails 132 to provide a pair of guide rails 132 . ) is configured to be movable along the

Accordingly, the slide-type solar panel 130 may be in a state drawn into the interior of the base unit 102 through the slit hole 105 as shown in FIGS. 6 (a) and 7 (a), and FIG. 6 (b) and 7 (b) as shown in the slit hole 105 may be configured to be drawn out from the base portion (102).

In the present invention, a linear actuator 140 for drawing in or withdrawing the solar panel 130 into the base portion 102 through the slit hole 105 or from the base portion 102 is configured inside the base portion 102 . .

The linear actuator 140 is configured in a "C" shape, and the actuator body 141 having rotation support portions 141a and 141b formed at both ends thereof, and a rod having a predetermined length, and a computerized bolt having a thread on the outer circumferential surface. A rotating rod 143 configured to be rotatable on both ends of the rotating support formed on both sides of the actuator body 141, and configured to be movable along the longitudinal direction of the actuator body 141, the rotating rod 143 A moving block 144 configured to pass through the rotating rod 143 and connected in the form of a ball-screw to move forward and backward along the actuator body 141 according to the rotation of the rotating rod 143, and the actuator body 141 A motor 145 installed on one side of the to rotate the rotating rod 143 and one end fixed to the moving block 147 and the other end of the “L”-shaped frame provided at the rear end of the slide-type solar panel 130 . It is fixedly installed on the 134 , and is configured to include a connection member 147 connecting the slide-type solar panel 130 and the moving block 147 .

With the above configuration, when the motor 145 rotates in one direction in a state in which the slide-type solar panel 130 is drawn into the base portion 102 as shown in FIGS. 6 (a) and 7 (a), Accordingly, as the rotating rod 143 rotates and the moving block 144 moves forward, the slide-type solar panel 130 connected to the moving block 144 also moves forward together with FIGS. 6 (b) and 7 (b) and Similarly, the slide-type solar panel 130 is drawn out from the base unit 102 through the slit hole 105 .

In the present invention, the controller 120 drives the motor 145 in one direction when the measured illuminance of the illuminance sensor 124 is greater than or equal to a preset value so that the slide-type solar panel 130 is withdrawn from the base unit 102 . Power generation by the slide-type solar panel 130 may be configured to charge the battery 114 .

In addition, when the measurement report of the illuminance sensor 124 is less than or equal to the preset value, the motor 145 is driven in the other direction so that the slide-type solar panel 130 is drawn into the base unit 102 , so that the slide-type solar panel 130 . ) can be stored in the interior of the base portion 102 .

As such, in the present invention, when sunlight is floating during the daytime, the slide-type solar panel 130 is drawn out from the base unit 102 to charge the battery 114 by photovoltaic power generation, and the sunlight at night time In the absence of this, since the slide-type solar panel 130 is drawn into the base unit 102 to be in a storage state, the service life of the solar panel 130 can be improved, and in addition, it is fixed to the base unit 102 in a fixed form. Compared to installing a solar panel, the solar panel 130 having a larger area can be configured, thereby increasing the amount of power generation and improving the charging efficiency of the battery 114 .

8 and 9, the rubber cone 10' according to the third embodiment of the present invention, the LED light reciprocates within a predetermined angle range, so that the vehicle driver or pedestrian can more reliably recognize the rubber cone. The reciprocating rotation light emitting unit 150 is configured.

In the first embodiment, the plurality of LED lights 110 are fixedly installed on the upper outer peripheral surface of the cone part 103, but in the third embodiment, the plurality of LED lights are not directly fixedly installed on the cone part 103', but the cone part. A reciprocating rotation light emitting unit 150 that reciprocates inside the 103' is configured, and the light emitted from the reciprocating rotation light emitting unit 150 forms a transparent window 108 formed on the top of the cone part 103'. It is configured to be discharged to the outside through.

Specifically, the cone part 103' is formed in a cylindrical shape in the form of a lower beam in the middle of the upper part 103a and the lower part 103b, and a transparent window made of a transparent material connecting the upper part 103a and the lower part 103b. (108) can be configured.

That is, in the third embodiment, the cone part 103' is divided into two parts, an upper cone part 103a and a lower cone part 103b, and the upper cone part 103a and the lower cone part 103b are connected by a transparent window 108. composed in the form

The reciprocating rotation light emitting unit 150 is configured to include a shaft portion 151 , a rotation cone 152 , an LED module 154 , and a rotation driving unit 160 .

The shaft portion 151 is installed on the inner central axis of the cone portion 103', the upper end is fixed to the center of the ceiling of the cone portion 103', and the lower end is an extension bar 106 extending from the inner circumferential surface of the cone portion 103' toward the center. ) is fixed to the inner end and is installed to be supported by the shaft support portion 106a disposed on the central axis of the cone portion 103'.

The rotary cone 152 is made of a cone-shaped cylinder, and the bottom disk 152a is integrally provided at the lower end, and the shaft portion 151 is penetrated through the center of the bottom disk 152a to the shaft portion 151. With respect to the rotary cone 152 is configured to be rotatable.

In addition, the outer peripheral surface of the rotary cone 152 is disposed at the same height as the transparent window 108 is configured to face the transparent window (108).

The LED module 154 has a configuration in which light is emitted by receiving power from the battery 114 by the control unit 120, and by being installed at equal intervals on the outer peripheral surface of the rotating cone 152, the LED module 154 is turned on. The light emitted at the time may be configured to be emitted to the outside through the transparent window 108 .

The rotary driving unit 160 is configured to drive the rotary cone 152 to reciprocate within a predetermined range, and includes an electric motor 161, a cam member 162, a pin member 163, and a connecting bar 165. is configured to

The electric motor 161 may be configured to be fixedly installed on the extension bar 106 fixedly installed inside the cone part 103', and is driven to be driven and controlled by the controller 120 .

The cam member 162 is coupled to the driving shaft 161a of the electric motor 161 and is configured to rotate according to the driving of the electric motor 161 .

The pin member 163 is integrally protruded from the lower surface of the bottom disk 152a of the rotating cone 152, and is configured to be fixedly installed at an edge deviated from the center of the bottom disk 152a.

One end of the connecting bar 165 is configured to be rotatably connected to the eccentric shaft 162a of the cam member 162 , and the other end is configured to be rotatably connected to the pin member 163 .

With the above configuration, when the electric motor 161 is driven, the cam member 162 rotates and repeats the operation of pushing or pulling the connecting bar 165 , thereby the pin member 163 connected to the connecting bar 165 . While being pushed or pulled, the rotary cone 152 may be rotated in one direction in a predetermined angle range and a reciprocating rotation movement may be made in the other direction.

Accordingly, in a state in which the plurality of LED modules are turned on under the control of the control unit 120, the rotary cone 152 reciprocates in a predetermined angle range according to the driving of the electric motor 161, so that an external vehicle driver or The prevention of safety accidents will be made more reliable by enabling pedestrians to see more clearly about the rubber cone.

In the above, the present invention has been shown and described in relation to a preferred embodiment for illustrating the principle of the present invention, but the present invention is not limited to the configuration and operation as shown and described as such. Rather, it will be understood by those skilled in the art that many changes and modifications to the present invention are possible without departing from the spirit and scope of the appended utility model registration claims. Accordingly, all such suitable alterations and modifications and equivalents should be considered to fall within the scope of the present invention.

10...Labacon
101... body
102...base part
103...Konbu
112...Solar panel
114...Battery
120...control unit
121...Charging control unit
122...LED control
124...Light sensor
130...Slide-type solar panel
140...linear actuator
141...actuator body
143...rotating rod
144...moving block
145...Motor
147...connection member
150...Reciprocating light emitting unit
151...shaft
152...Rotating cone
154...LED module
160...Rotational drive
161...Electric motor
162...Cam member
163...pin member
165...connection bar

Claims (4)

a body part supported in contact with the ground and formed in a square plate shape, the body part including a base part having an inclined surface formed on the side surface and a cone part integrally extending from the base part to the upper part;
A plurality of LED lights installed at equal intervals along the upper outer peripheral surface of the cone to emit light to the outside;
a solar panel installed on the inclined surface to convert solar energy into electrical energy to generate electricity;
a battery installed inside the main body, the electricity generated from the solar panel is charged, and the charged electricity is used for the plurality of LEDs;
an illuminance sensor installed in the main body to measure illuminance and output the measured illuminance to the control unit;
It is installed inside the base part, charges the battery with electricity generated from the solar panel, supplies power of the battery to the plurality of LEDs to control the operation of the plurality of LEDs, and receives from the illuminance sensor A control unit for controlling to turn on the plurality of LED lights when the measured illuminance is less than or equal to a preset value;
A slide-type solar panel for charging the battery by being drawn into the base part through a slit hole formed on the side surface of the base part or drawn out laterally from the base part to charge the battery;
A linear actuator is configured inside the base part to draw in or withdraw the slide-type solar panel through the slit hole,
The linear actuator is
an actuator body having rotation support portions formed at both ends;
a rotation rod made in the form of a rod having a predetermined length, in the form of a computerized bolt having a thread formed on an outer circumferential surface, both ends of which are configured to be rotatable to the rotation support;
A moving block configured to be movable along the longitudinal direction of the actuator body and through which the rotating rod is passed through and connected to the rotating rod in the form of a ball-screw to move forward and backward along the actuator body according to the rotation of the rotating rod ;
a motor installed on one side of the actuator body to rotate the rotating rod;
One end is fixed to the moving block, the other end is fixed to the frame provided at the rear end of the slide-type solar panel, a connecting member for connecting the slide-type solar panel and the moving block;
It constitutes a reciprocating light emitting unit that reciprocates within the cone part, and the light emitted from the reciprocating rotation light emitting unit is configured to be emitted to the outside through a transparent window formed in the cone part,
The reciprocating rotation light emitting unit,
It is installed on the inner central axis of the cone part, the upper end is fixed to the center of the ceiling of the cone part, and the lower end is fixed to the inner end of the extension bar extending from the inner circumferential surface of the cone part toward the center and disposed on the central axis of the cone part. A shaft that is installed to be supported on the branch;
a rotary cone formed in a cone-shaped cylinder and integrally provided with a bottom disk at the lower end, and configured to be rotatable through the shaft portion in the center of the bottom disk;
an LED module that receives power from the battery by the control unit to light it and is installed at equal intervals on the outer circumferential surface of the rotating cone to emit light to the outside through the transparent window;
and a rotation driving unit for driving the rotating cone to reciprocate in a predetermined angle range.
The rotary drive unit,
an electric motor fixedly installed on an extension bar fixedly installed inside the cone part and driven and controlled by the control unit;
a cam member coupled to the driving shaft of the electric motor and rotating according to the driving of the electric motor;
a pin member integrally protruding from the lower surface of the bottom disk and fixedly installed at an edge deviated from the center of the bottom disk;
One end is configured to be rotatably on the eccentric shaft of the cam member, the other end is configured to be rotatably connected to the pin member, and a connection bar configured to reciprocate the rotary cone according to the rotation of the cam member. Lavacon, characterized in that.
The method of claim 1,
Lavacon, characterized in that the side of the base is electrically connected to the control unit and provided with a charging jack for charging the battery.
The method of claim 1,
Each of the plurality of LED lights is installed on the outer surface of the cone portion, Lavacon, characterized in that it is installed to protrude from the outer surface of the cone portion or is configured to be installed in the form embedded in the cone portion.
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