JP3226596U - Rotating screen rotation speed detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the manufacturing cost, to avoid the invasion of dust, not to be influenced by the external light rays, to avoid the error of transmitting and receiving the infrared rays, the cumulative error is small, and the change of the rotation speed. Provided is a rotating screen rotation speed detecting device capable of detecting in real time. SOLUTION: A base 1, a housing 3 for mounting a rotary screen, a motor 4, a communication infrared receiving tube 5, a communication infrared transmitting tube 6, a phase angle infrared receiving tube 7 and a phase angle infrared transmitting tube 8 are provided. The motor is attached to the base, the housing is connected to the output terminal of the base, the mounting cavity 9 is provided at the center of rotation of the motor, the communication infrared receiving tube is provided in the mounting cavity, and the communication infrared transmitting tube is the housing. Mounted on the center of rotation of the housing and provided corresponding to the communication infrared receiving tube, the phase angle infrared transmitting tube is installed on the side of the housing facing the base, and the phase angle infrared receiving tube is installed on the side of the base facing the housing. .. [Selection diagram] Fig. 3

Description

The present invention relates to the field of rotary screens, and more particularly to a rotation speed detection device for rotary screens.

There are two types of conventional rotary screen rotation speed detection devices, one that employs an encoder and one that detects rotation speed by a method of detecting infrared pulses.

The system that employs such an encoder enables one rotation, has a graduation at each phase angle, directly reads the graduation, outputs the corresponding data according to the graduation, and drives the LED.

The method of detecting the infrared pulse is a method of calculating the previous rotation speed and determining the next rotation speed. This method is simple, but the drawback is that the speed of the next lap may be different from the speed of the previous lap, and the screen displayed in this way will be blurry or incomplete, resulting in sunlight or other infrared rays. Is susceptible to. In addition, since it cannot be sealed, it is easily dusty and the signal will not reach after a long time.

This utility model provides a rotational speed detection device for a rotating screen to solve at least one technical problem. ..

In order to solve the above problems, as one mode of the present utility model, a rotation speed detection device for a rotary screen includes a base (1), a housing (3) for mounting the rotary screen (2), and a motor (4). ), a communication infrared receiver tube (5), a communication infrared transmitter tube (6), a phase angle infrared receiver tube (7), and a phase angle infrared transmitter tube (8), and the motor (4) Is attached to the base (1), the housing (3) is connected to an output terminal of the base (1), and a mounting cavity (9) is provided at a rotation center of the motor (4). The communication infrared receiver tube (5) is provided in the mounting cavity (9), the communication infrared transmitter tube (6) is mounted at the center of rotation of the housing (3), and the communication infrared receiver tube is provided. (Five)
Corresponding to the position of the phase angle infrared transmitter tube (8) is the pedestal of the housing (3).
The phase angle infrared receiving tube (7) is provided on the side facing the (1), and is attached to the side facing the housing (3) of the pedestal (1).

Preferably, a coil is provided in each of the base and the housing.

Preferably, a substrate is attached to the bottom of the base.

Preferably, a slide rail is attached to the bottom of the base.

Preferably, a plurality of phase angle infrared receiving tubes are attached to the base.

Since the above-mentioned technology is adopted, the manufacturing cost of the present utility model is low, it is possible to avoid the intrusion of dust, and at the same time, it is possible to avoid the error of infrared transmission and reception without being affected by the external light rays. Further, the accumulated error is small, and the change in the rotation speed can be detected in real time. The screen can be adjusted by changing the rotation speed.

FIG. 1 is a diagram schematically showing the overall configuration of the present invention. FIG. 2 is a schematic exploded view of the present invention. FIG. 3 is a schematic sectional view of the present utility model.

[Explanation of symbols]
1, pedestal, 2, rotating screen, 3, housing, 4, motor, 5, communication infrared receiver tube, 6, communication infrared transmitter tube, 7, phase angle infrared receiver tube, 8, phase angle infrared transmitter tube, 9, cavity ,Ten
, Coil, 11, substrate, 12, slide rail, 13, host motherboard, 14, drive plate

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings, but the present invention may be implemented in various comprehensive forms, which are limited by the claims.

One aspect of the present utility model is a base 1, a housing 3 for mounting a rotating screen 2, a motor 4, a communication infrared receiving tube 5, a communication infrared transmitting tube 6, a phase angle infrared receiving tube 7, and a phase. A rotation speed detection device for a rotating screen provided with an angular infrared transmission tube (8). A mounting cavity 9 is provided at the rotation center of the motor 4, and the communication infrared transmission tube 6 is attached to the rotation center of the housing 3 in the mounting cavity 9, and the communication infrared receiving tube is provided.
The phase angle infrared transmitter tube 8 is provided corresponding to the position of 5, and the phase angle infrared transmitter tube 8 is mounted on the side of the housing 3 facing the pedestal 1. The infrared receiving tube 7 is attached to the side of the pedestal 1 facing the housing 3.

By installing an infrared transmitter/receiver in the middle part of the base 1 and housing 3, it is possible to prevent dust from entering and at the same time avoid the influence of external light and avoid infrared transmitter/receiver errors. You can

Preferably, a coil 10 is provided in each of the base 1 and the housing 3.
The two mated sets of coils 10 allow power to be supplied to the host motherboard 13 mounted in the housing 3. In addition, the base 1 has a motor 4 and a communication infrared receiving tube.
5. A drive plate 14 for driving the phase angle infrared receiving tube 7 is attached. Here, the communication infrared receiving tube 5 and the communication infrared transmitting tube 6 may be used for communication and data transfer between the host board 13 and the drive plate 14, and the phase angle infrared receiving tube 7 and the phase angle infrared receiving tube 7 may be used. Transmission tube 8 is motor 4
It is used to detect the phase and rotation speed. It should be noted that the detection of the rotation speed is a conventional technique, and a description thereof will be omitted here.

The rotation speed of the brushless motor is controlled by changing the AC frequency of the current input to the brushless motor stator coil, and the motor speed is also affected by the load.Therefore, signal feedback is performed for each phase angle of the brushless motor. The drive plate 14 can calculate the angular velocity by this feedback signal, and the signal can be calculated via the communication infrared receiving tube 5 and the communication infrared transmitting tube 6. The infrared method is transmitted to the host board 13, and the host motherboard 13 uses video decoding to convert the video stream into a rotation display format, drive the LED, and update and display the rotation display screen 2 in real time. You can

A substrate 11 is preferably attached to the bottom of the pedestal 1. Preferably, the substrate 11
A slide rail 12 is attached to the bottom of the. Thus, this utility model pedestal 1
Can be easily attached by the slide 12.

Preferably, the base 1 is provided with a plurality of the phase angle infrared receiving tubes 7. Preferably, the motor used in this utility model is a brushless motor, which has three phases,
That is, when the motor makes one rotation, three trigger signals are fed back, and the rotation speed of the motor is calculated by the three trigger signals. Also, the motor in this utility model is hollow,
The communication infrared ray receiving tube 5 is mounted in the mounting cavity 9 so that it does not become out of alignment due to rotation. In the drive plate 14, while driving the motor 4, the angular phase infrared transmission pipe 8 transmits a signal, the phase infrared reception pipe 7 receives the signal, and the drive plate 14 obtains a rotation speed. The drive plate 14 also communicates with the host board 13 via the communication infrared receiver tube 5, the communication infrared transmitter tube 6, and the phase angle infrared receiver tube 7, and there is a video decoder inside, and the output video stream is directly sent to the FPGA. Then, the FPGA rearranges the screen stream, and the FPGA outputs corresponding data to the LED driving IC from different positions of the rotation speed and the positioning infrared ray.

Also, there are three position feedback signals each time the motor rotates, which is two more than the prior art measured speed. For example, divide the three positions into ABC and record the rotation time and position from A to B, B to C, C to A. For example, the time from A to B is 1 second, C to C is 0.9 seconds,
It can be seen that it takes 0.8 seconds from C to A. There is only one speed to go around like that. In this way, the integration error is reduced, the change in rotation speed is detected in real time, and the screen can be adjusted according to the change in rotation speed.

The above is only a preferred embodiment of the present utility model and is not intended to limit the present utility model, and various modifications and alterations of the present invention are possible for those skilled in the art. Any modifications, equivalent replacements, improvements etc. made within the spirit and principle of this Utility Model should be included in the scope of protection of this Utility Model.

Claims (5)

A rotating speed detecting device for a rotating screen, comprising: a base (1), a housing (3) for mounting the rotating screen (2), a motor (4), a communication infrared receiver tube (5), and a communication infrared transmitter. A tube (6), a phase angle infrared receiving tube (7), and a phase angle infrared transmitting tube (8) are provided, and the motor (4) is attached to the base (1) and the housing (3). ) Is
Connected to the output terminal of the base (1), a mounting cavity (9) is provided at the center of rotation of the motor (4), and the communication infrared receiver tube (5) is provided in the mounting cavity (9). The communication infrared transmitter tube (6) is attached to the center of rotation of the housing (3) and is provided corresponding to the position of the communication infrared receiver tube (5). Tube (8)
Is provided on the side of the housing (3) facing the pedestal (1), and the phase angle infrared receiving tube (7
) Is attached to the side of the pedestal (1) facing the housing (3), and the rotational speed detection device for a rotary screen is characterized in that. The rotation speed detecting device for a rotary screen according to claim 1, wherein a coil (10) is provided on each of the base (1) and the housing (3). A substrate (11) is attached to the bottom of the base (1).
A rotation speed detection device for a rotating screen according to. 4. The rotation speed detecting device for a rotating screen according to claim 3, wherein a slide rail (12) is attached to the bottom of the substrate (11). 2. The rotating speed detecting device for a rotating screen according to claim 1, wherein a plurality of the phase angle infrared receiving tubes (7) are attached to the base (1).