CN212920949U - Electric power planning design ruler with laser positioning and measuring functions - Google Patents

Abstract

The application discloses electric power planning design chi with laser positioning measurement function includes: the sliding groove frame is arranged above the supporting frame in a spanning mode and is arranged in a reciprocating sliding mode along the longitudinal direction of the supporting frame; the chute frame includes: the laser generating block and the reflecting plate are arranged on the upper surface of the sliding chute frame, a sliding chute is transversely arranged along the sliding chute frame, and the top surface of the sliding chute is open; a transverse convex strip is arranged on the bottom surface of the sliding groove; when the electric power drawing is drawn, the positioning accuracy and the measurement precision of the drawing point in the drawing can be improved, the measurement result is not influenced by the visual angle of an observer, and the measurement result precision is high.

Description

Electric power planning design ruler with laser positioning and measuring functions

Technical Field

The application relates to an electric power planning design ruler with laser positioning measurement function, and belongs to the technical field of electric power design.

Background

In the power planning design, a common tool is a power planning ruler, different points and coordinates can be conveniently drawn on a drawing when a planning drawing is drawn through the power planning ruler, the distance between any two points of the conventional power planning ruler needs to be measured through scales, and a measurement result is greatly influenced by the sight angle of an observer and is difficult to accurately unify.

SUMMERY OF THE UTILITY MODEL

The application provides an electric power planning design ruler with laser positioning measurement function for solving the technical problems.

The application provides an electric power planning design chi with laser positioning measurement function includes: the sliding groove frame is arranged above the supporting frame in a spanning mode and is arranged in a reciprocating sliding mode along the longitudinal direction of the supporting frame;

the chute frame includes: the laser generating block and the reflecting plate are arranged on the upper surface of the sliding chute frame, a sliding chute is transversely arranged along the sliding chute frame, and the top surface of the sliding chute is open; a transverse convex strip is arranged on the bottom surface of the sliding groove;

the laser generating block and the reflecting plate are arranged in the sliding groove and are arranged in a sliding mode along the transverse convex strips;

the laser generating block includes: the positioning laser source is arranged on the bottom surface of the laser generating block and is arranged opposite to the bottom surface of the supporting frame to emit laser;

the measuring laser source is arranged on the side wall of the laser generating block and is arranged opposite to the reflecting plate for emitting laser;

the measuring sensor is arranged on the side wall of the laser generating block and is electrically connected with a display arranged on the top surface of the laser generating block.

Preferably, the laser generating block includes: the bottom surface of the sliding box is provided with a groove which extends transversely along the sliding box and penetrates through two opposite sides of the sliding box;

two opposite outer walls of the sliding box are in sliding contact with the inner wall of the sliding groove;

the positioning laser source, the measuring laser source and the measuring sensor are arranged in the sliding box.

Preferably, the slide box comprises: the second handle is arranged on the top surface of the sliding box.

Preferably, the reflection plate includes: the sliding plate and the first handle are provided with grooves which are opposite to the transverse convex strips on the top surface of the sliding plate, and the grooves are arranged on the transverse convex strips in a sliding manner;

the first handle is arranged on the top surface of the sliding plate;

the two sides of the sliding plate are in sliding contact with the inner side wall of the sliding groove.

Preferably, the support frame includes: the device comprises transverse supporting rods and longitudinal supporting rods, wherein the transverse supporting rods are arranged in pairs, and the transverse supporting rods are symmetrically arranged at two ends of the longitudinal supporting rods and are respectively connected with two ends of the longitudinal supporting rods; the longitudinal support rod is arranged along the longitudinal extension of the support frame.

Preferably, the outer side wall of the longitudinal support rod is provided with a sliding groove along the longitudinal direction thereof;

the sliding groove frame comprises sliding support legs which are respectively arranged at two ends of the sliding groove frame, and the extending ends of the sliding support legs are connected with the sliding grooves on the longitudinal support rods in a sliding mode.

Preferably, the method comprises the following steps: the sliding support legs are provided with sliding convex strips on opposite side walls of the extending ends, and the sliding convex strips are arranged in the sliding grooves in a sliding mode; the fixed end of the sliding support leg is provided with a fixed bolt and is connected with the frame body of the sliding groove frame through the fixed bolt.

Preferably, the method comprises the following steps: and the paper pressing plate is arranged on the bottom surface of the supporting frame.

The beneficial effects that this application can produce include:

1) the application provides an electric power planning design chi with laser positioning measurement function can improve when drawing the electric power drawing, draws point location accuracy and measurement accuracy in the drawing, and this measuring result is not influenced by observer visual angle, and the measuring result precision is high. Display screen and slip range finding board through slip range finding trigger laser generator end, through the distance between the laser measurement two to obtain the distance between arbitrary two points on the drawing in real time, improve measurement accuracy, need not to count the scale repeatedly, improve measurement of efficiency and read, draw the efficiency of drawing.

Drawings

Fig. 1 is a schematic top view of a power planning design rule with laser positioning and measuring functions according to the present application;

fig. 2 is a schematic cross-sectional view of a front view of an electric power planning design rule with a laser positioning measurement function according to the present application;

illustration of the drawings:

10. a transverse support rod; 12. a longitudinal support bar; 15. pressing a paper board; 152. drawing; 21. fixing the bolt; 212. a sliding leg; 213. sliding convex strips; 22. a chute frame; 25. a sliding groove; 251. transverse convex strips; 24. a reflective plate; 241. a first handle; 242. a slide plate; 23. a laser generating block; 231. a slide box; 232. a second handle; 233. positioning a laser source; 234. a measurement laser source.

Detailed Description

The present application will be described in detail with reference to examples, but the present application is not limited to these examples.

Referring to fig. 1, the present application provides an electric power planning design rule with laser positioning measurement function, including: the sliding groove 25 frame 22 is arranged above the supporting frame in a spanning mode and longitudinally slides along the supporting frame in a reciprocating mode; the runner 25 frame 22 includes: the laser generating block 23, the reflecting plate 24, the sliding slot 25 is set up horizontally along the sliding slot 25 on the top surface of the frame 22 of the sliding slot 25, the top surface of the sliding slot 25 is open, set up the horizontal convex strip 251 on the bottom surface of the sliding slot 25; the laser generating block 23 and the reflecting plate 24 are arranged in the sliding slot 25 and are arranged in a sliding way along the transverse convex strip 251;

the laser generating block 23 includes: the positioning laser source 233, the measuring laser source 234 and the measuring sensor, wherein the positioning laser source 233 is arranged on the bottom surface of the laser generating block 23 and is arranged opposite to the bottom surface of the supporting frame to emit laser;

the measuring laser source 234 is arranged on the side wall of the laser generating block 23 and is arranged opposite to the reflecting plate 24 for emitting laser; the measuring sensor is arranged on the side wall of the laser generating block 23 and is electrically connected with a display arranged on the top surface of the laser generating block 23.

The top surface of the measuring scale is provided with a sliding groove 25, a transverse convex strip 251 is arranged in the sliding groove 25, a laser generating block 23 and a reflecting plate 24 are arranged on the transverse convex strip 251 and slide along the transverse convex strip 251, the laser generating block 23 and the reflecting plate 24 slide along the transverse convex strip 251, the bottom surface of the laser generating block 23 emits laser beams, after the laser beams are positioned on a drawing 152, the positions sliding to the required distance to be measured are determined, the side wall of the laser generating block 23 faces the reflecting plate 24 to generate measuring laser beams, after the laser beams are emitted to be reflected back, a measuring sensor on the laser generating block 23 obtains time difference, and the distance from the side wall of the laser generating block 23 to the reflecting plate 24 is obtained through calculation according to the time difference; and the number of the interval measurement results is displayed on the top surface of the laser generating block 23.

By adopting the testing method, the distance between the laser generating block 23 and the reflecting plate 24 can be accurately acquired only by sliding the laser generating block and the reflecting plate, the positioning is accurate, the measuring result is directly output, and the measuring method is not influenced by the measuring visual angle direction.

Details not described may be set up with reference to conventional settings of laser rangefinders. The light sources are arranged in a common laser light source arrangement mode, and details are not described here.

Referring to fig. 2, preferably, the laser generating block 23 includes: the bottom surface of the sliding box 231 is provided with a groove, and the groove transversely extends along the sliding box 231 and penetrates through two opposite sides of the sliding box 231; two opposite outer walls of the sliding box 231 are in sliding contact with the inner wall of the sliding groove 25; a positioning laser source 233, a measurement laser source 234, and a measurement sensor are disposed within the traveler box 231. The grooves are matched with the transverse ribs 251, and the sliding box 231 can slide along the transverse ribs 251, so that the positioning control movement is facilitated.

Preferably, the slide box 231 includes a second handle 232, and the second handle 232 is provided on the top surface of the slide box 231. The movement of the glide box 231 is conveniently controlled by providing a handle.

Preferably, the reflection plate 24 includes: the sliding plate 242 and the first handle 241, the top surface of the sliding plate 242 is provided with a groove opposite to the transverse convex strip 251, and the groove is arranged on the transverse convex strip 251 in a sliding manner; the first handle 241 is arranged on the top surface of the sliding plate 242; both sides of the slide plate 242 are in sliding contact with the inner side walls of the slide groove 25.

This arrangement enables the reflecting plate 24 to slide smoothly along the slide groove 25 and facilitates the fixing of the position.

Referring to fig. 1, preferably, the support frame includes: the pair-arranged transverse supporting rods 10 and the pair-arranged longitudinal supporting rods 12 are symmetrically arranged at two ends of the longitudinal supporting rods 12, and the transverse supporting rods 10 are respectively connected with two ends of the longitudinal supporting rods 12; the longitudinal support bar 12 extends in the longitudinal direction of the support frame.

The supporting frame can be enclosed into a rectangular frame by the transverse supporting rod 10 and the longitudinal supporting rod 12, so that the sliding groove 25 and the rack 22 can conveniently slide on the supporting frame. Specifically, if the transverse support rods 10 comprise a first transverse support rod 10 and a second transverse support rod 10, the longitudinal support rods 12 comprise a first longitudinal support rod 12 and a second longitudinal support rod 12, and two ends of the first transverse support rod 10 are respectively connected with a first end of the first longitudinal support rod 12 and a first end of the second longitudinal support rod 12; two ends of the second transverse supporting rod 10 are respectively connected with the second end of the first longitudinal supporting rod 12 and the second end of the second longitudinal supporting rod 12.

Referring to fig. 2, preferably, the outer side wall of the longitudinal support bar 12 is provided with a sliding groove along the longitudinal direction thereof; the sliding groove 25 frame 22 comprises sliding legs 212 which are respectively arranged at two ends of the sliding groove 25 frame 22, and the extending ends of the sliding legs 212 are connected with the sliding grooves on the longitudinal support bar 12 in a sliding way. In use, the sliding legs 212 slide along the runners to effect longitudinal movement of the frame 22 of the runner 25.

Preferably, the method comprises the following steps: the fixing bolt 21 and the sliding convex strip 213, the sliding convex strip 213 is arranged on the opposite side wall of the extending end of the sliding supporting leg 212, and the sliding convex strip 213 is arranged in the sliding groove in a sliding way; the fixed end of the sliding leg 212 is provided with a fixed bolt 21 and is connected with the frame body of the sliding slot 25 frame 22 through the fixed bolt 21.

By arranging the fixing bolt 21, the position of the sliding chute 25 frame 22 on the longitudinal support rod 12 can be conveniently fixed according to requirements, and the measurement precision is improved. A gap is left between the sliding leg 212 and the frame body, and the clamping degree of the sliding leg 212 and the sliding groove can be adjusted through the fixing bolt 21, so that the position of the frame 22 of the sliding groove 25 is controlled.

Preferably, the method comprises the following steps: a paper pressing plate 15, the paper pressing plate 15 is arranged on the bottom surface of the supporting frame. The paper pressing plate 15 is arranged to facilitate pressing of the drawing paper 152, and measurement accuracy is improved.

The slide box 231, the paper pressing plate 15 and the laser generating block 23 can be made of hard transparent materials according to requirements.

Reference throughout this specification to "one embodiment," "another embodiment," "an embodiment," "a preferred embodiment," or the like, means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment described generally in this application. The appearances of the same phrase in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the scope of the disclosure to effect such feature, structure, or characteristic in connection with other embodiments.

Although the present application has been described herein with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More specifically, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure and claims of this application. In addition to variations and modifications in the component parts and/or arrangements, other uses will also be apparent to those skilled in the art.

Claims (8)

1. An electric power planning design chi with laser positioning measurement function which characterized in that includes: the sliding groove (25) frame (22) is arranged above the supporting frame in a straddling manner and is arranged in a reciprocating sliding manner along the longitudinal direction of the supporting frame;

the runner (25) frame (22) comprises: the laser generator comprises a laser generating block (23) and a reflecting plate (24), wherein a sliding groove (25) is transversely arranged on the top surface of a frame (22) of the sliding groove (25) along the frame (22) of the sliding groove (25), and the top surface of the sliding groove (25) is open; a transverse convex strip (251) is arranged on the bottom surface of the sliding groove (25);

the laser generating block (23) and the reflecting plate (24) are arranged in the sliding groove (25) and are arranged in a sliding mode along the transverse convex strip (251);

the laser generation block (23) includes: the laser positioning device comprises a positioning laser source (233), a measuring laser source (234) and a measuring sensor, wherein the positioning laser source (233) is arranged on the bottom surface of a laser generating block (23) and is arranged opposite to the bottom surface of the supporting frame for emitting laser;

the measuring laser source (234) is arranged on the side wall of the laser generating block (23) and is arranged opposite to the reflecting plate (24) for emitting laser;

the measuring sensor is arranged on the side wall of the laser generating block (23) and is electrically connected with a display arranged on the top surface of the laser generating block (23).

2. A power planning ruler with laser positioning measurement function according to claim 1, characterized in that the laser generation block (23) comprises: the bottom surface of the sliding box (231) is provided with a groove, and the groove transversely extends along the sliding box (231) and penetrates through two opposite sides of the sliding box (231);

the two opposite outer walls of the sliding box (231) are in sliding contact with the inner wall of the sliding groove (25);

the positioning laser source (233), the measuring laser source (234) and the measuring sensor are arranged in the slide box (231).

3. An electric power planning ruler with laser positioning measurement function according to claim 2, characterized in that the slide box (231) comprises: and the second handle (232) is arranged on the top surface of the sliding box (231).

4. A power planning ruler with laser positioning measurement function according to claim 1, characterized in that the reflection plate (24) comprises: the sliding plate (242) and the first handle (241), a groove is arranged on the top surface of the sliding plate (242) opposite to the transverse convex strip (251), and the groove is arranged on the transverse convex strip (251) in a sliding manner;

the first handle (241) is arranged on the top surface of the sliding plate (242);

the two sides of the sliding plate (242) are in sliding contact with the inner side wall of the sliding groove (25).

5. The power planning ruler with laser positioning measurement function of claim 1, wherein the support frame comprises: the pair-arranged transverse supporting rods (10) and the pair-arranged longitudinal supporting rods (12), wherein the transverse supporting rods (10) are symmetrically arranged at two ends of the longitudinal supporting rods (12) and are respectively connected with two ends of the longitudinal supporting rods (12); the longitudinal support rod (12) is arranged along the longitudinal extension of the support frame.

6. The power planning design rule with laser positioning and measuring function according to claim 5, characterized in that the outer side wall of the longitudinal support rod (12) is provided with a sliding groove along the longitudinal direction thereof;

the sliding groove (25) frame (22) comprises sliding legs (212) which are respectively arranged at two ends of the sliding groove (25) frame (22), and the extending ends of the sliding legs (212) are in sliding connection with the sliding grooves on the longitudinal support rod (12).

7. The power planning ruler with laser positioning measurement function according to claim 5, comprising: the sliding support leg structure comprises a fixing bolt (21) and sliding convex strips (213), wherein the sliding convex strips (213) are arranged on the opposite side walls of the extending ends of the sliding support legs (212), and the sliding convex strips (213) are arranged in the sliding grooves in a sliding mode; the fixed end of the sliding leg (212) is provided with a fixed bolt (21) and is connected with the frame body of the sliding groove (25) frame (22) through the fixed bolt (21).

8. A power planning ruler with laser positioning measurement function according to claim 1, comprising: and the paper pressing plate (15) is arranged on the bottom surface of the supporting frame.

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