CN117031914A - Deep-light mirror clock based on led lamp display time - Google Patents

Abstract

The invention provides a deep-drawing mirror clock based on LED lamp display time. The deep-light mirror clock combines the deep-light mirror principle with the led clock, achieves the infinite circulation watching effect of lamplight when the clock works, and can bring full future feeling and technological feeling to the vision of people.

Description

Deep-light mirror clock based on led lamp display time

Technical Field

The invention relates to a deep-drawing mirror and LED lamp control technology, in particular to a deep-drawing mirror clock based on LED lamp display time.

Background

The deep-light mirror is a popular product in recent years, and the basic principle of the deep-light mirror is that a front half lens and a rear single-sided mirror are arranged, so that light between the half lens and the single-sided mirror generates an infinite circulation visual effect. In recent years, patents or products designed by the principle include a deep-drawing mirror, a deep-drawing mirror sound box, a deep-drawing mirror light box, a deep-drawing mirror cabinet, a wheel with a deep-drawing mirror effect, and the like. There is currently much room for development of deep-seated mirror products. At present, a deep-drawing mirror clock which combines a deep-drawing mirror with a clock, can display time and can create an infinite circulation effect of the deep-drawing mirror is not provided.

Disclosure of Invention

1. Technical problem to be solved

For development of a deep-drawing mirror product, the invention provides a deep-drawing mirror clock based on the display time of a led lamp. Solves the following technical problems:

1. a separate led light strip is not used as a pointer for the led clock displaying time.

2. At present, although led clocks are available, most of the led clocks are clocks of an led display screen, which is unfavorable for combining a deep-light mirror to enable light to generate an infinite circulation visual effect.

3. There is no deep-drawing mirror clock product in which the deep-drawing mirror principle is combined with the led clock work.

2. Technical proposal

The technical scheme adopted for solving the technical problems is as follows: the utility model provides a led lamp deep-light mirror clock, includes the clock frame, the positive fixed semi-lens of clock frame, built-in single-sided mirror arranges a plurality of led lamp area and led digital lamp on the single-sided mirror, realizes the infinitely circular viewing effect of led clock during operation light, gives people the vision and brings full future sense and technological sense.

Further is: the front mirror surface of the clock with the deep-light mirror adopts a half lens, the half lens can be divided into a unidirectional perspective mirror, a bidirectional perspective mirror and the like due to perspective parameters of materials, and the built-in mirror surface of the clock adopts a single-sided mirror for reflecting and refracting light and the like, so that original single lamplight is converted into an infinite circulation effect.

Further is: the led lamp belts are arranged in the indication direction of the hour hand or the second hand scale, can be in the form of a lamp bead strip or a lamp tube, and can be selected according to actual conditions.

3. Advantageous effects

The beneficial effects of the invention are as follows:

1. the invention provides a deep-drawing mirror clock based on LED lamp display time.

2. The deep-drawing mirror clock can be used for displaying the deep-drawing mirror effect of the led clock, so that the led lamp generates an infinite-circulation visual effect when the led clock displays time.

Drawings

FIG. 1 is a schematic view of the visual effect of the present invention;

FIG. 2 is a structural intent of the present invention;

FIG. 3 is a schematic structural design of the built-in single-sided mirror of the present invention;

fig. 4 is a schematic diagram of a clock circuit controller according to the present invention.

Fig. 5 is a schematic diagram of the time-indicating led lamp band-pass circuit control of the present invention.

FIG. 6 is a schematic diagram of the circuit control of the second-reading led lamp, the led digital lamp and the center led lamp in the present invention.

FIG. 7 is a diagram showing the visual effect of the present invention at 12 points in time.

Detailed Description

The invention is further described below with reference to the drawings and the detailed description. It will be apparent that the described embodiments are only some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1: the most basic structural and functional principles of the present invention

The led lamp deep-light mirror clock shown in fig. 2 has the following basic structure: the clock comprises a clock outer frame 3, and the front surface of the clock outer frame 3 is fixedly connected with a half lens 1. The clock outer frame 3 is fixedly connected with the single-sided mirror 2, and a clock circuit controller 5 is fixed behind the single-sided mirror. The clock circuit controller has an access power interface 6. The single-sided mirror has a time display light strip 4 embedded or fixed on the surface. The light bands include time indication light bands 'L1' to 'L60', led digital lamps 'Ls 1' to 'Ls 12', a central round lamp 'Lz', reading second led lamps 'Lm 1' to 'Lm 60', and the like, as shown in fig. 3 (note: 60 bands of schematic indication light bands only draw 12 bands), and fig. 4.

As shown in fig. 2, the functional principle of the invention is as follows: the front mirror surface of the clock with the deep-light mirror adopts a half lens, the half lens can be divided into a unidirectional perspective mirror, a bidirectional perspective mirror and the like due to perspective parameters of materials, and the clock built-in mirror adopts a single-sided mirror for reflecting, refracting and the like. When the deep-drawing mirror clock works, the internal light is stronger than the external light, so that the original single light is converted into an infinite circulation visual effect under the combined action of the half lens and the single-sided mirror, and the effect is shown in figure 1.

Example 2: arrangement with built-in single mirror and led lamp

Arrangement of led lamps: the deep-light mirror clock is internally provided with a single-sided mirror with a circular light-emitting lamp at the center, 60 led lamp bands are arranged around the center in the deep-light mirror clock for indicating the hour and minute values, and a group of led light-emitting words from 1 to 12 are arranged around the center. In addition, 60 led lamps were added to the outer edge to display the read seconds. Led lamp layout and operation effect are shown in fig. 3 and 1.

For 60 led lamp strips, two led lamps with the same color are needed for each led lamp strip to simultaneously indicate hours and minutes, and the led lamps with the same color are connected in parallel to form a small unit. The led lamps of the two colors are arranged at intervals. As shown in fig. 5.

Fixation mode 1 of single-sided mirror and led lamp: the LED lamp strip, LED luminous words and the like can be directly fixed on the surface of the single-sided mirror 2.

Fixing mode 2 of single-sided mirror and led lamp: the single-sided mirror 2 is cut as shown in fig. 3, and is used for embedding an LED lamp, LED light-emitting word, and the like.

Fixing mode 3 of single-sided mirror and led lamp: the single-sided mirror 2 is perforated as shown in fig. 3, and led lamps are fixed to the surface of the single-sided mirror, and the perforation in the single-sided mirror is used for leading out wires of the led lamps.

Example 3: wiring and basic circuit structure of led lamp

60 time indication lamp strips, wherein led lamp beads formed by the lamp strips are connected in parallel, and each lamp strip is used as a unit to be connected with a time circuit controller;

the 60 reading second led lamps are respectively connected with the time circuit controller;

the central led lamp and 12 led digital lamps are connected in parallel as a unit to connect with the time circuit controller 5; the above wiring and circuit configuration are shown in fig. 5 and 6.

Example 4: control principle of time circuit controller

Principle of on-off of led lamp reading second display: the 60 read second led lights illuminate the next light every second clockwise.

Because 60 led strips are commonly used to indicate the hours and minutes, the following strips are named for their function. The principle of jumping of led lamp strip needle display: the read second led lamp in the 12-point direction is used as an initial, and each time the read second led lamp is turned on for one circle (every 60 seconds), the led lamp band of the minute hand is displayed to jump to the lamp band of the next minute.

Principle of beating of the hour hand display of led lamps: after the led lamp belt of the display minute hand is initially lighted for one circle by taking the 12-point direction as the initial lighting, the led lamp belt of the display hour hand jumps to the next integral point value to be lighted. During the period, the scale value indicated by the minute hand led lamp strip influences the hour hand led lamp strip to gradually jump to forward the bright display towards the next whole point direction.

The gradual change principle of the hour hand led lamp strip to the next whole point is as follows: every 12 minutes, the hour led strip jumps to the next led strip.

led lamp hour hand sharing: since the display of the same direction minute hand and hour hand shares one light band, the led clock may share the same light band to display the hour hand and minute hand, for example, 12 points, 1 point, 5 points, 2 points, 10 points, 3 points, 16 points, 4 points, 21 points, 5 points, 27 points, 6 points, 32 points, 7 points, 38 points, 8 points, 43 points, 9 points, 49, 10 points, 54 points, and 11 points 59. For example, 12-point finishing, as shown in fig. 7.

The central led lamp and 12 led digital lamps are connected in parallel and are used as a unit to connect with the time circuit controller 5, and the led deep-light clock works normally;

while the foregoing is directed to embodiments of the present invention, other and further details of the invention may be had by the present invention, it should be understood that the foregoing description is merely illustrative of the present invention and that no limitations are intended to the scope of the invention, except insofar as modifications, equivalents, improvements or modifications are within the spirit and principles of the invention.

Claims (5)

1. The deep-light mirror clock based on the LED lamp display time comprises a clock outer frame 3, and the front surface of the clock outer frame 3 is fixedly connected with a half lens 1. The clock outer frame 3 is fixedly connected with the single-sided mirror 2, and a clock circuit controller 5 is fixed behind the single-sided mirror. The clock circuit controller has an access power interface 6. The single-sided mirror has a time display light strip 4 embedded or fixed on the surface. The lamp bands include time indication lamp bands "L1" to "L60", led digital lamps "Ls1" to "Ls12", a center round lamp "Lz", and read second led lamps "Lm1" to "Lm60".

2. The deep-drawing mirror clock of claim 1, wherein a round light-emitting lamp is arranged at the center of the single-sided mirror, 60 led lamp bands are arranged around the center inside and used for indicating the hour and minute values, and a group of led light-emitting words from '1' to '12' are arranged at the periphery. In addition, 60 led lamps were added to the outer edge to display the read seconds.

3. The LED lamp strip, LED luminous words and the like can be directly fixed on the surface of the single-sided mirror 2 in a fixing mode of the single-sided mirror and the LED lamp; the single-sided mirror 2 can be cut for embedding an LED lamp and LED luminous words; the single-sided mirror 2 may also be perforated to fix the led lamp on the surface of the single-sided mirror, and the perforation on the single-sided mirror is used for leading out the wires of the led lamp.

4. The 60 time indicating lamp strips according to claim 1, wherein led lamp beads formed by the lamp strips are connected in parallel, and each lamp strip is used as a unit to be connected with a time circuit controller; the 60 reading second led lamps are respectively and independently connected with the time circuit controller; the central led lamp and the 12 led digital lamps are connected in parallel as a unit to the time circuit controller 5.

5. The time 60 indicator light strips of claim 1 are composed of led lamps of two colors which are separated in parallel, and can be combined by other colors, and the colors of the light are convenient to distinguish and watch.