阅读说明：本技术 具有姿势控制功能的激光标线仪 (Laser line marking instrument with posture control function ) 是由 陈智锋 萧育华 陈华邦 K·阮 C·P·D·陈 于 2018-09-12 设计创作，主要内容包括：一种激光标线仪包括：姿势控制装置,其包括至少一个传感器(10),配置成感测使用者的姿势和/或移动；和控制器,其与姿势控制装置通信,用于接收来自传感器的信号并且基于接收到的信号产生用于标线仪的控制指令,控制指令至少包括标线仪能够投射的激光束图案的ON/OFF状态。(A laser striping machine comprising: a posture control device comprising at least one sensor (10) configured to sense a posture and/or movement of a user; and a controller in communication with the attitude control device for receiving the signals from the sensor and generating control instructions for the reticle based ON the received signals, the control instructions including at least an ON/OFF state of a laser beam pattern that the reticle is capable of projecting.)

1. A laser striping machine comprising:

a position control device comprising at least one sensor configured to sense a position and/or movement of a user; and

a controller in communication with the attitude control device for receiving the signals from the sensor and generating control instructions for the reticle based ON the received signals, the control instructions including at least an ON/OFF state of a laser beam pattern that the reticle is capable of projecting.

2. The laser striper of claim 1, wherein at least two sensors are provided that are arranged at substantially the same height, and the controller is configured to generate a control command to activate the horizontal laser beam when a user slides from a first sensor of the at least two sensors to a second sensor of the at least two sensors, and to generate a control command to deactivate the horizontal laser beam when a user slides from the second sensor of the at least two sensors to the first sensor of the at least two sensors.

3. The laser striper of claim 1 or claim 2, wherein at least two sensors are provided arranged at different heights, and the controller is configured to generate a control command to activate the vertical laser beam when a user slides from one of the at least two sensors to another of the at least two sensors, and to generate a control command to deactivate the vertical laser beam when a user slides from the another of the at least two sensors to the one of the at least two sensors.

4. The laser striplet of any one of claims 1 to 3, wherein at least one sensor is provided which is adapted to be clicked on by a user, and the controller is configured to generate control commands to activate/deactivate the plumb laser spot when the user clicks on this sensor.

5. The laser striplet of any one of claims 1 to 3, wherein there are at least two sensors adapted to be stroked by a user, and the controller is configured to generate control instructions to activate/deactivate the plumb laser spot when a user slides from or to a certain other of the at least two sensors.

6. The laser striper of any one of claims 1 to 5, wherein the striper comprises an HMI and at least some of the sensors are disposed on or below a screen of the HMI.

7. The laser striper of claim 6, wherein the screen is provided with markings corresponding to the sensors to guide the sliding and/or clicking actions of the user.

8. The laser striper of any one of claims 1 to 7, wherein the striper comprises a housing and at least some of the sensors are arranged on or inside the housing.

9. The laser striping machine of any one of claims 1 to 8, wherein when a user is sensed by both sensors in sequence, there is a time delay between the signals of the two sensors, and the controller is configured to determine different laser ON/OFF commands based ON the signals of the sensors and the time delay.

10. The laser striping machine of any one of claims 1 to 9, wherein the sensor has a sensing range of 10 to 20 mm.

11. The laser striper of claim 10, wherein the sensor is selected from the group consisting of: an infrared sensor, a capacitive sensor, a passive infrared sensor, a resistive sensor, and/or a magnetic sensor.

12. The laser striper of claim 1, wherein the sensor comprises a sensor capable of capturing a user's posture and/or movement when the user is within a capture zone of the sensor.

13. The laser striper of claim 11 or claim 12, wherein the sensor is configured to capture an image of the user when the user is exposed to radiation within a capture area of the sensor.

14. The laser striper of claim 13, wherein the radiation comprises visible or invisible light.

15. The laser striper of claim 14, further comprising an emitter configured to emit visible or non-visible light.

16. The laser striping machine of any one of claims 12 to 15, wherein the sensor has a sensing range of a few to tens of meters.

17. The laser striping machine of any one of claims 12 to 16, wherein the sensor is selected from the group consisting of: a camera, an infrared sensor, and/or a passive infrared sensor.

18. The laser striper of any one of claims 1 to 17, wherein the sensor has an adjustable sensing range.

Technical Field

The present application relates to a laser striping machine having a gesture control function for controlling operation of the laser striping machine.

Background

Laser striping machines or tools are commonly used in the construction and finishing arts. Conventional laser striping machines include at least one laser beam emitter for emitting a laser beam which is projected onto a target surface to form a predetermined pattern which can be used as a reference to facilitate work in construction or modification.

Laser striping machines typically have an HMI through which a user can control the operation of the laser striping machine. The HMI of existing laser striping machines includes physical buttons for entering user instructions, such as entering initial settings, selecting and triggering different projection modes, and the like. Prior to operation, the laser reticle is typically adjusted to a desired position and orientation, and the act of pressing a button often affects the position and orientation of the reticle that has been adjusted, possibly resulting in errors or skewing of the projected pattern of the reticle.

In addition, when the reticle is designed to project more types of patterns (e.g., dots, lines, planes, crosses, etc.), the HMI needs to be equipped with more buttons, and thus occupies a larger area on the reticle.

To reduce the number of buttons, a single button design has been proposed that allows the user to toggle ON/OFF different types of laser patterns that are periodically presented. This mode can be confusing to the user when the user only wishes to control one or a small number of laser patterns.

Disclosure of Invention

It is an object of the present application to mitigate laser striping defects caused by physical buttons.

To achieve this object, in one aspect, the present application provides a laser striping machine comprising: a position control device comprising at least one sensor configured to sense a position and/or movement of a user; and a controller in communication with the attitude control device for receiving the signals from the sensor and generating control instructions for the reticle based ON the received signals, the control instructions including at least an ON/OFF state of a laser beam pattern that the reticle is capable of projecting.

According to one possible embodiment, at least two sensors arranged at substantially the same height are provided, and the controller is configured to generate a control command to activate the horizontal laser beam when a user slides from a first sensor of the at least two sensors to a second sensor of the at least two sensors, and to generate a control command to deactivate the horizontal laser beam when a user slides from the second sensor of the at least two sensors to the first sensor of the at least two sensors.

According to one possible embodiment, at least two sensors arranged at different heights are provided, and the controller is configured to generate a control command to activate the vertical laser beam when a user slides from one of the at least two sensors to another of the at least two sensors, and to generate a control command to deactivate the vertical laser beam when a user slides from the another of the at least two sensors to the one of the at least two sensors.

According to one possible embodiment, at least one sensor is provided adapted to be clicked by a user, and the controller is configured to generate a control command to activate/deactivate the plumb laser point when this sensor is clicked by the user.

According to one possible embodiment, there are at least two sensors adapted to be stroked by a user, and the controller is configured to generate a control command to activate/deactivate the plumb laser point when the user slides from or to a certain other of the at least two sensors.

According to one possible embodiment, the reticle comprises an HMI and at least some of the sensors are arranged on or below a screen of the HMI.

According to one possible embodiment, the screen is provided with markings corresponding to the sensors to guide the sliding and/or clicking actions of the user.

According to one possible embodiment, the reticle comprises a housing and at least some of the sensors are arranged on or inside the housing.

According to one possible embodiment, when the user is sensed by two sensors in sequence, there is a time delay between the signals of the two sensors, and the controller is configured to determine different laser ON/OFF commands based ON the signals of the sensors and the time delay.

According to one possible embodiment, the sensor has a sensing range of 10 to 20 mm.

According to one possible embodiment, the sensor is selected from: an infrared sensor, a capacitive sensor, a passive infrared sensor, a resistive sensor, and/or a magnetic sensor.

According to one possible embodiment, the sensor comprises a sensor capable of capturing the posture and/or movement of the user when the user is located within the capture area of the sensor.

According to one possible embodiment, the sensor is configured to capture an image of the user when the user is exposed to radiation within a capture area of the sensor.

According to a possible embodiment, the radiation comprises visible light or invisible light.

According to a possible embodiment, the laser striping machine further comprises an emitter configured to emit visible or non-visible light.

According to one possible embodiment, the sensor has a sensing range of several meters to several tens of meters.

According to one possible embodiment, the sensor is selected from: a camera, an infrared sensor, and/or a passive infrared sensor.

According to one possible embodiment, the sensor has an adjustable sensing range.

In accordance with the present application, the reticle includes a gesture control feature to replace the physical buttons used with conventional reticles. When the line marking instrument is operated, the instruction can be input through the sliding or clicking action of the body part of the user, and physical pressing is not needed. The disadvantages of laser striping machines due to physical buttons are eliminated.

Other advantages and aspects of the present application will become apparent from the detailed description that follows.

Drawings

The present application will become more fully understood from the detailed description given below with reference to the accompanying drawings, in which:

FIG. 1 is a schematic perspective view of a laser striping machine according to one embodiment of the present application;

FIG. 2 is a schematic rear view of the laser striper of FIG. 1;

FIG. 3 is a schematic diagram of an HMI of a laser striping machine showing attitude control sensors and indicator marks of the HMI according to a short range sensing embodiment of the present application;

FIGS. 4 and 5 are schematic diagrams representing actions that can be performed on the HMI to input commands to the reticle;

FIGS. 6 and 7 are schematic perspective views of a laser striping machine showing gesture control functions provided at other locations of the striping machine and actions that can be performed with respect to the gesture control functions;

FIG. 8 is a schematic perspective view of a different type of laser striping machine, which is also equipped with attitude control functionality;

FIG. 9 is a schematic diagram showing the principle of sensing movement action of two sensors according to the present application; and

FIG. 10 is a schematic perspective view of a laser striper according to a long distance sensing embodiment of the present application.

Detailed Description

The present application relates generally to a laser striping machine. The laser striping machine may be of any type and may have any form. Thus, although the present application will be described based on a particular form of laser striping machine, other forms of laser striping machines are also contemplated within the scope of the present application.

Fig. 1 and 2 show a laser striping machine to which the techniques of the present application can be applied, with fig. 1 showing the top, front and right sides of the striping machine, and fig. 2 showing the back side of the striping machine. It can be seen that the reticle includes a housing 1 in/on which the various functional elements of the reticle are mounted. A front projection window 2 is exposed to the front side of the housing 1, the front projection window 2 including a horizontal branch and a vertical branch extending upward from the horizontal branch. The horizontal laser beam and the vertical laser beam can be projected through the horizontal branch and the vertical branch, respectively. A top projection window 3 is exposed at the top side of the housing 1, through which top projection window 3 a plumb laser spot can be projected.

On one inclined rear side portion of the housing 1, an HMI 4 is provided, by which a user can input a command to the reticle, and the HMI 4 can display information of the state and operation of the reticle.

The basic idea of the present application is to eliminate the push type physical button used in the HMI of the conventional line striper, and for this purpose, the line striper is equipped with a posture control device for sensing the posture of the user.

By way of example, the HMI 4 is configured as a gesture control device capable of sensing gestures and/or actions of a user's body part, in particular a hand or a finger, and translating the sensed gestures into input instructions for controlling the operation of the reticle.

In order to sense the posture of the user, the present application recognizes that the short distance sensing manner and the long distance sensing manner can be used for the posture sensing of the user.

As a short-range sensing approach, some proximity sensors are investigated and evaluated. In general, the user's finger is close to the gesture control device, for example, within a short distance range of 20mm, so the working range of the sensor should cover this distance range. In addition, sensing accuracy, stability (under various environmental conditions, such as light, temperature, etc.), sensitivity, etc. are also key factors in selecting a sensor. Applicants have found that IR (infrared) sensors and capacitive sensors meet all of these requirements.

An IR sensor as used herein is equipped with an IR emitter for emitting IR radiation and an IR receiver for sensing IR radiation reflected from a user's hand or fingers. When the user's finger approaches the IR light emitted from the IR emitter, the IR light is reflected by the finger and the reflected IR light is sensed by the IR receiver. The operating range of the IR sensor is adjustable and suitable for short range sensing applications (e.g., 10 to 20 mm).

The capacitive sensor used herein is capable of sensing a change in capacitance caused when a user's finger contacts or approaches the capacitive sensor. The sensing range of such sensors can be sensed through glass or plastic, so a capacitive sensor can be mounted inside the housing. The working range of the capacitive sensor is also adjustable and suitable for short range sensing applications (e.g., 10 to 20 mm).

It will be appreciated that other types of proximity sensors, such as passive IR sensors, resistive sensors, laser beam sensors, magnetic sensors, etc., may also meet the short range sensing requirements, although some adaptations may be required; for example, when using a passive IR sensor, some specially designed lens may need to be employed to enable short-range gesture sensing.

Next, the HMI 4 was modified to an attitude control device employing a proximity sensor having an operating range of 10 to 20 mm. The proximity sensors are arranged within a range defined by the HMI 4 in a distributed pattern suitable for sensing the posture (gesture) of the user's finger. One particular pattern of distribution is presented in FIG. 3, where sensors S1, S2, and S3 are distributed on a horizontal line, and sensors S4, S2, and S5 are distributed on a vertical line, the horizontal and vertical lines intersecting sensor S2. The sensor S6 is disposed below the lowermost sensor S5 on the vertical line, but the sensor S6 may be disposed at another position on the HMI 4.

If the sensing fields of the sensors S1 to S6 (e.g., capacitive type sensors) can pass through the screen of the HMI 4, the sensors may be installed under the screen. On the other hand, if the screen HMI 4 through which the sensing fields of the sensors S1 to S6 cannot pass, the sensors may be mounted on the screen.

The laterally disposed sensors S1, S2, and S3 may be used to sense substantially lateral (horizontal) movement of the user ' S finger, the longitudinally disposed sensors S4, S2, and S5 may be used to sense substantially longitudinal (vertical) movement of the user ' S finger, and the sensor S6 may be used to sense a click of the user ' S finger. In order to guide the motion of the user' S fingers, cross marks 5 are formed on the screen corresponding to the lateral sensors S1, S2 and S3 and the longitudinal sensors S4, S2 and S5, and spot or circular click marks 6 are formed on the screen corresponding to the sensors S6.

As shown in fig. 4, as the user's finger approaches and moves along the branch of the cross-hair 5 in the horizontal and/or vertical direction, as indicated by the arrowed line, the laterally or longitudinally arranged sensor senses the action of the user's finger and the controller of the striping machine receives signals from the sensor to determine the user's intention and then generates corresponding instructions to control the striping machine to activate/deactivate the horizontal laser beam and/or the vertical laser beam, which passes through the front projection window 2. For example, when the finger is moved from sensor S1 to S3, the horizontal laser beam is activated, and when the finger is moved from sensor S3 to S1, the horizontal laser beam is deactivated; when the finger is moved from the sensor S5 to S4, the vertical laser beam is activated, and when the finger is moved from the sensor S4 to S5, the vertical laser beam is turned off.

As shown in fig. 5, when the user 'S finger hits the click mark 6, the sensor S6 senses the motion of the user' S finger, and the controller of the striper generates a corresponding command to control the striper to activate the plumb laser spot, which passes through the top window 3, and to be turned off when the finger hits the click mark 6 again.

Alternatively or additionally, the reticle may include sensors disposed at other locations to form the attitude control means. As an example, as shown in fig. 6 and 7, the sensor Sa is arranged at a first end of the horizontal branch close to the front projection window 2, and the sensor Sb is arranged at a second end of the horizontal branch close to the front projection window 2. The sensor Sc is arranged at the top front edge of the housing 1 above the vertical branch of the front projection window 2, the sensor Sd is arranged at the top rear edge of the housing 1, and the sensors Sc and Sd are located on the front and rear sides of the top window 3. The sensors Sa to Sd may be mounted within the housing 1 or on the housing 1, depending on whether their sensing fields are able to pass through the housing 1.

The controller of the striping machine is capable of receiving the signal sensors from Sa-Sd and generating corresponding instructions to control the striping machine to activate/deactivate the laser beam. For example, as shown in fig. 6, the horizontal laser beam is activated when the finger is moved horizontally from sensor Sa to sensor Sb, and the horizontal laser beam is deactivated when the finger is moved horizontally from sensor Sb to sensor Sa; the vertical laser beam is activated when the finger is moved vertically from sensor Sa or Sb to sensor Sc, and is deactivated when the finger is moved vertically from sensor Sc to sensor Sa or Sb; the plumb laser spot is activated when a finger is moved from the sensor Sc to the sensor Sd, or one of the sensors Sc and Sd is clicked, and the plumb laser spot is deactivated when a finger is moved from the sensor Sd to the sensor Sc, or the other of the sensors Sc and Sd is clicked, or one of the sensors Sc and Sd is clicked again.

Other types of finger motions, such as clicking on two sensors at the same time, sliding three or more sensors along a non-linear path, etc., may be used to cause the controller to generate other commands.

Other types of laser beam activation/deactivation operations can also be implemented by arranging corresponding sensors and associating input commands with sensed sensor signals. .

The attitude control device formed using the sensor of the present application can also be applied to other types of reticle instruments. For example, as shown in fig. 8, for a striper having laser emitting panels 7 and 8, sensors Sa and Sb may be disposed at positions below the front panel 7, a sensor Sc may be disposed at the front panel 7, and a sensor Sd may be disposed at the top panel 8. The triggering operation of the laser activation/deactivation in relation to the sensors Sa to Sd may be similar to that described above with reference to fig. 6 and 7.

It is understood that for all embodiments of the present application, the activation/deactivation operation of all laser beams (horizontal, vertical, dot, cross, etc.) can be achieved by clicking or sliding (moving) between the respective sensors. However, sliding between the sensors can provide greater reliability, as can be appreciated with reference to FIG. 9.

Fig. 9 shows the signals of two sensors. The state of the output signal of the first sensor changes (e.g., jumps) as the finger approaches the first sensor, and the state of the output signal of the second sensor changes (e.g., jumps) as the finger moves toward and approaches the second sensor. There is a trigger delay deltat, e.g., 75ms to 750ms, from the change in state of the output signal of the first sensor to the change in state of the output signal of the second sensor. The trigger delay Δ t can prevent false triggering of activation/deactivation of the laser beam. Different trigger delays may be used for the controller to determine different laser beam activation/deactivation commands.

According to another aspect of the present application, as shown in fig. 10, a long-range sensing style gesture control device may include a sensor (e.g., CMOS sensor) 10 capable of sensing gestures and/or motions of a user's body part over a relatively long distance, e.g., several meters to tens of meters, such as about 10 meters. The sensor 10 may be mounted on the housing 1 or within the housing 1, for example, on the backside of the laser striplet. The sensing range of the sensor 10 may also be adjustable. The sensing signal of the sensor 10 is transmitted to the controller to determine the user's intention, and the controller then generates corresponding instructions to control the operation of the laser striper (similar to that described above with reference to the short sensing embodiment). More than one sensor 10 may also be provided in the laser striping machine.

The long range sensing mode sensor 10 may be a sensor that is capable of capturing (filming) an image of a part of the user's body when the user is exposed to radiation within the capture area of the sensor 10. For example, the radiation may be visible or invisible light. The radiation may come from ambient light, or from a radiation emitter 11 of a laser striping machine.

The radiation emitter 11, if present, may also be mounted on or in the housing 1, and more than one radiation emitter 11 may also be provided in the laser striping machine.

As an example of the long distance sensing type sensor 10, a sensor capable of capturing an image of a user may be used. For example, the sensor 10 may be a miniature camera that is capable of capturing (filming) an image of the user in visible light.

As other examples of the long range sensing mode sensor 10, an IR sensor or a passive IR sensor may be used to capture an image of a user in invisible light. For an IR sensor, it includes an IR emitter and an IR receiver. The IR emitter emits IR radiation. The IR radiation emitted from the IR emitter is incident into the user's body part, and then an image of the user's body part exposed to the IR radiation can be sensed by the IP receiver. For a passive IR sensor, it may comprise only an IR receiver for sensing a user's body part when the user's body part is exposed to IR radiation from ambient light.

Other types of long distance sensing means sensors (with or without a radiation source) may also be used herein.

Short and long range sensing modes can also be used in combination in the same laser striper.

It can be seen that in accordance with the present application, the laser striper includes a gesture control device in place of the physical buttons used in conventional laser stripers. In operation of the reticle, commands can be entered by sliding, clicking or other types of actions by the user's fingers, hands or other body parts, without the need for a pressing action. Laser striping defects due to physical buttons can be eliminated.

Although the present application has been described herein with reference to specific exemplary embodiments, the scope of the present application is not intended to be limited to the details shown. Various modifications may be made to these details without departing from the underlying principles of the application.