CN212900686U - Height gauge probe connection structure for automobile part machining - Google Patents

Abstract

The utility model discloses a height gage probe connecting structure for processing automobile parts, which comprises a sliding plate, a placing plate and a regulating plate arranged on one side of the upper end face of the placing plate, wherein the upper end face of the regulating plate is provided with a second sliding groove in the middle, and both sides of the regulating plate are provided with first sliding grooves, two groups of second sliding shafts are symmetrically and fixedly arranged in the second sliding grooves, two groups of second sliding blocks are arranged on the outer edge surface of the second sliding shafts in a sliding fit manner, the upper end face of each second sliding block extends out of the second sliding groove and is fixedly connected with a second extending plate, a plurality of groups of first limiting holes are equidistantly arranged on both sides of the upper end face of the regulating plate, a group of first sliding shafts are fixedly arranged in the first sliding grooves, the height gage probe connecting structure for processing automobile parts is reasonable in structure, is convenient for regulating a height gage during measurement, and is convenient for reducing the shaking amplitude of a base under the action of external force, the practicability is strong.

Description

Height gauge probe connection structure for automobile part machining

Technical Field

The utility model belongs to the technical field of the altitude gauge, concretely relates to altitude gauge probe connection structure is used in automobile parts processing.

Background

The excellent performance of the height gauge makes the height gauge have wide application space in the fields of electronics, cutters, plastics, precision parts, springs, stamping parts, connectors, dies, military industry, aerospace, universities, scientific research institutions and the like, the height gauge, namely a two-dimensional measuring instrument, transmits the graph of a product to a telephone through an image system and measures the size of the product through related measuring software, such as two-dimensional sizes of circles, radians, angles, distances and the like, and the height gauge is currently used in the industries of plastics, hardware, dies, electronics, semiconductors and the like and is the best tool for guaranteeing the qualified product size.

Height gage wide application and each big field, current height gage are usually placed height gage and await measuring when measuring on same desktop respectively with the piece, need pull to suitable position to the height gage during the measurement, easily cause wearing and tearing to the base of desktop and height gage, and current height gage when measuring, the base rocks the range great when encountering external force, and then influences measuring accuracy.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a car parts processing is with height gage probe connection structure to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a height gauge probe connecting structure for machining automobile parts comprises a sliding plate, a placing plate and an adjusting plate arranged on one side of the upper end face of the placing plate, wherein a second sliding groove is formed in the middle of the upper end face of the adjusting plate, first sliding grooves are formed in two sides of the adjusting plate, two groups of second sliding shafts are symmetrically and fixedly installed in the second sliding grooves, a group of second sliding blocks are installed on the outer edge surfaces of the two groups of second sliding shafts in a sliding fit mode, second sliding grooves extend out of the upper end face of each second sliding block and are fixedly connected with a second extending plate, and a plurality of groups of first limiting holes are formed in two sides of the upper end face of the adjusting plate at equal intervals;

a set of first sliding shaft is fixedly installed in the first sliding groove, a set of first sliding block is installed on the outer edge face of the first sliding shaft in a sliding fit mode, one side of the first sliding block extends out of the first sliding groove and is fixedly connected with the second extending plate, and a fixing hole matched with the first limiting hole is formed in the upper end face of the second extending plate.

Preferably, two sets of inserting grooves are symmetrically formed in two sides of the upper end face of the placing plate, two sets of inserting holes communicated into the inserting grooves are symmetrically formed in two sides of the placing plate, fixing blocks fixedly connected with the side faces of the adjusting plate are arranged in the two sets of inserting grooves, one end of each fixing block extends out of the inserting grooves, first extending plates are constructed on two sides of each fixing block, the joint of the upper end face of each first extending plate and the connecting portion of the placing plate is fixedly connected through cross bolts, and fastening bolts with one ends abutted against one side of the fixing blocks are installed in the inserting holes.

Preferably, the upper end face of the second extension plate is fixedly connected with a movable plate in the middle, a movable groove is formed in one side of the movable plate, a set of knobs are installed on the upper end face of the movable plate, a set of threaded shafts movably installed in the movable groove are connected to the lower end face of each knob, a set of rectangular blocks are installed on the outer edge face of each threaded shaft in a threaded fit mode, and one ends of the rectangular blocks extend out of the movable groove and are fixedly connected with a sliding plate.

Preferably, a third sliding groove is formed in the sliding plate in the middle, multiple groups of second limiting holes are formed in the upper end face of the sliding plate at equal intervals, a set of third sliding shafts are fixedly mounted in the third sliding groove, a third sliding block is mounted on the outer edge face of each third sliding shaft in a sliding fit mode, a set of U-shaped plate is extended out of each of two sides of each third sliding block, a third sliding groove is formed in each of the two sides of each third sliding block, a scale is mounted on the upper end face of each U-shaped plate, a third extending plate is fixedly connected to one side of the upper end face of each U-shaped plate, a threaded hole matched with each second limiting hole is formed in each third extending plate, a sleeve is fixedly connected to the lower end face of each U-shaped plate in the middle, a set of probes.

Preferably, a placing groove is formed in one side of the upper end face of the placing plate, supporting legs are fixedly mounted at four corners of the lower end face of the placing plate, and vacuum chucks are fixedly connected to the lower end face of each supporting leg.

The utility model discloses a technological effect and advantage: according to the height gauge probe connecting structure for machining the automobile parts, due to the fact that the second sliding block is installed in a sliding fit mode with the second sliding shaft, the movable plate can be pushed, the second sliding block slides in the second sliding groove, and the second extending plate is driven to move, so that the position of the probe is adjusted, the situation that the table top and a base of a height gauge are abraded due to dragging of the second extending plate is avoided; benefit from the setting of first sliding shaft and first slider, one side of first slider extends first sliding tray and with second extension board fixed connection, the fixed orifices of the first spacing hole of cooperation is seted up to the up end of second extension board, can twist in first spacing hole and fixed orifices with a set of bolt, realizes fixed to the second extension board, reduces the second extension board and meets with external force and takes place the range of rocking, reduces the influence to measuring accuracy.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged schematic view of the structure at A in FIG. 1 according to the present invention;

fig. 3 is an enlarged schematic view of the structure at B in fig. 1 according to the present invention.

In the figure: the probe comprises a placing plate 1, a placing groove 101, a supporting leg 2, a vacuum chuck 201, a fixing block 3, a first extending plate 301, a fastening bolt 4, a regulating plate 5, a first sliding groove 501, a second sliding groove 502, a first limiting hole 503, a first sliding shaft 6, a first sliding block 601, a second extending plate 602, a second sliding shaft 7, a second sliding block 701, a movable plate 8, a movable groove 801, a knob 9, a threaded shaft 901, a sliding plate 10, a third sliding groove 1001, a second limiting hole 1002, a third sliding shaft 11, a third sliding block 1101, a third sliding block 12U-shaped plate 1201, a third extending plate 1201, a sleeve 13 and a probe 1301.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Unless defined otherwise, all references to up, down, left, right, front, back, inner and outer directions herein are to be interpreted as referring to up, down, left, right, front, back, inner and outer directions in the drawings to which the invention is applied, and all references are hereby incorporated herein by reference.

The utility model provides a height gage probe connection structure for processing automobile parts as shown in figures 1-3, which comprises a sliding plate 10, a placing plate 1 and an adjusting plate 5 arranged on one side of the upper end face of the placing plate 1, wherein the upper end face of the adjusting plate 5 is centrally provided with a second sliding groove 502, both sides of the adjusting plate 5 are provided with first sliding grooves 501, the adjusting plate 5 is in a rectangular plate structure, two groups of second sliding shafts 7 are symmetrically and fixedly arranged in the second sliding grooves 502, two groups of second sliding blocks 701 are arranged on the outer edge face of the second sliding shafts 7 in a sliding fit manner, the upper end face of each second sliding block 701 extends out of the second sliding groove 502 and is fixedly connected with a second extending plate 602, the second extending plate 602 is in a U-shaped plate structure, a plurality of groups of first limiting holes 503 are arranged on both sides of the upper end face of the adjusting plate 5 at equal intervals, the second sliding blocks 701 and the second sliding shafts 7 benefit from sliding fit installation, the movable plate 8 can be pushed, so that the second slider 701 slides in the second sliding groove 502 to drive the second extending plate 602 to move, thereby adjusting the position of the probe 1301, and avoiding dragging the second extending plate 602 to cause abrasion to a table top and a base of a height gauge;

a set of first sliding shaft 6 is fixedly installed in the first sliding groove 501, a set of first sliding block 601 is installed on the outer edge surface of the first sliding shaft 6 in a sliding fit manner, one side of the first sliding block 601 extends out of the first sliding groove 501 and is fixedly connected with the second extending plate 602, a fixing hole matched with the first limiting hole 503 is formed in the upper end surface of the second extending plate 602, due to the arrangement of the first sliding shaft 6 and the first sliding block 601, one side of the first sliding block 601 extends out of the first sliding groove 501 and is fixedly connected with the second extending plate 602, a fixing hole matched with the first limiting hole 503 is formed in the upper end surface of the second extending plate 602, a set of bolts can be screwed into the first limiting hole 503 and the fixing hole, so that the fixing of the second extending plate 602 is realized, the amplitude of shaking of the second extending plate 602 caused by external force is reduced, and the influence on the measurement accuracy is reduced.

Specifically, two sets of inserting grooves are symmetrically formed in the two sides of the upper end face of the placing plate 1, two sets of inserting holes communicated into the inserting grooves are symmetrically formed in the two sides of the placing plate 1, two sets of fixing blocks 3 fixedly connected with the side faces of the adjusting plate 5 are arranged in the inserting grooves, the fixing blocks 3 are rectangular block-shaped structures, one ends of the fixing blocks 3 extend out of the inserting grooves and are provided with first extending plates 301 in two sides, the first extending plates 301 are rectangular plate-shaped structures, the joint of the upper end face of each first extending plate 301 and the connecting portion of the placing plate 1 is fixedly connected with a cross bolt, and fastening bolts 4 with one ends butted to one side of the fixing blocks 3 are installed in the inserting holes.

Specifically, the upper end surface of the second extension plate 602 is fixedly connected with a movable plate 8 in the middle, the movable plate 8 is of a rectangular plate-shaped structure, a movable groove 801 is formed in one side of the movable plate 8, a set of knobs 9 are installed on the upper end surface of the movable plate 8, a set of threaded shafts 901 which are movably installed in the movable groove 801 are connected to the lower end surface of the knobs 9, a set of rectangular blocks are installed on the outer edge surface of the threaded shafts 901 in a threaded fit mode, threaded holes which are matched with the threaded shafts 901 to install covers are formed in the rectangular blocks, the movable groove 801 is extended out of one end of each rectangular block, a sliding plate 10 is fixedly connected with the corresponding rectangular plate.

Specifically, a third sliding groove 1001 is formed in the sliding plate 10 at the center, and a plurality of groups of second limiting holes 1002 are formed on the upper end surface of the sliding plate 10 at equal intervals, a set of third sliding shafts 11 is fixedly installed in the third sliding grooves 1001, a third slider 1101 is installed on the outer edge surface of the third sliding shaft 11 in a sliding fit manner, a third sliding groove 1001 extends from both sides of the third sliding block 1101 and is fixedly connected with a group of U-shaped plates 12, gauges are installed on the upper end surfaces of the U-shaped plates 12, and one side of the upper end surface of the U-shaped plate 12 is fixedly connected with a third extension plate 1201, the third extension plate 1201 is a rectangular plate-shaped structure, a threaded hole matched with the second limiting hole 1002 is formed in the third extending plate 1201, the lower terminal surface of U-shaped board 12 fixedly connected with sleeve 13 placed in the middle, fixed mounting has a set of probe 1301 in sleeve 13, the probe is installed to the one end of probe 1301.

Specifically, a placing groove 101 is formed in one side of the upper end face of the placing plate 1, supporting legs 2 are fixedly mounted on four corners of the lower end face of the placing plate 1, and vacuum chucks 201 are fixedly connected to the lower end face of each supporting leg 2.

The working principle of the height gauge probe connecting structure for processing the automobile parts is that when the height gauge probe connecting structure is used, an object to be measured can be placed in the placing groove 101, the movable plate 8 can be pushed, the second sliding block 701 slides in the second sliding groove 502 to drive the second extending plate 602 to move, a group of bolts can be screwed into the first limiting hole 503 and the fixing hole to fix the second extending plate 602, the knob 9 is rotated to rotate the threaded shaft 901, so that the rectangular block arranged on the outer edge surface of the threaded shaft 901 moves up and down to adjust the height of the probe 1301, the U-shaped plate 12 is pushed, the third sliding block 1101 slides in the third sliding groove 1001 to properly adjust the position of the probe 1301, a group of bolts can be screwed into the second limiting hole 1002 and the threaded hole formed in the third extending plate 1201 to fix the position of the probe 1301, and the object can be measured after the position of the probe 1301 is fixed, this automobile parts processing is with altitude gauge probe connection structure, it is rational in infrastructure, be convenient for adjust the altitude gauge when measuring, and be convenient for reduce the range that the base rocked by exogenic action, the practicality is strong.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications and variations can be made in the embodiments or in part of the technical features of the embodiments without departing from the spirit and the scope of the invention.

Claims (5)

1. The utility model provides a car parts processing is with height gage probe connection structure, includes sliding plate (10), places board (1) and sets up in regulating plate (5) of placing board (1) up end one side, its characterized in that: a second sliding groove (502) is formed in the middle of the upper end face of the adjusting plate (5), first sliding grooves (501) are formed in the two sides of the adjusting plate (5), two groups of second sliding shafts (7) are symmetrically and fixedly installed in the second sliding grooves (502), a group of second sliding blocks (701) are installed on the outer edge faces of the two groups of second sliding shafts (7) in a sliding fit mode, the second sliding grooves (502) extend out of the upper end face of each second sliding block (701) and are fixedly connected with second extending plates (602), and a plurality of groups of first limiting holes (503) are formed in the two sides of the upper end face of the adjusting plate (5) at equal intervals;

a set of first sliding shaft (6) is fixedly mounted in the first sliding groove (501), a set of first sliding block (601) is mounted on the outer edge surface of the first sliding shaft (6) in a sliding fit manner, one side of the first sliding block (601) extends out of the first sliding groove (501) and is fixedly connected with the second extending plate (602), and a fixing hole matched with the first limiting hole (503) is formed in the upper end surface of the second extending plate (602).

2. The height gauge probe connection structure for automobile part processing according to claim 1, wherein: two sets of inserting grooves are symmetrically formed in two sides of the upper end face of the placing plate (1), two sets of inserting holes communicated into the inserting grooves are symmetrically formed in two sides of the placing plate (1), two sets of fixing blocks (3) fixedly connected with the side faces of the adjusting plates (5) are arranged in the inserting grooves, one ends of the fixing blocks (3) extend out of the inserting grooves and two sides of the fixing blocks are constructed with first extending plates (301), the upper end face of each first extending plate (301) is fixedly connected with the joint of the placing plate (1) through cross bolts, and fastening bolts (4) with one end butted to one side of the fixing blocks (3) are installed in the inserting holes.

3. The height gauge probe connection structure for automobile part processing according to claim 1, wherein: the upper end face of the second extension plate (602) is fixedly connected with a movable plate (8) in the middle, a movable groove (801) is formed in one side of the movable plate (8), a group of knobs (9) are installed on the upper end face of the movable plate (8), a group of threaded shafts (901) which are movably installed in the movable groove (801) are connected to the lower end face of each knob (9), a group of rectangular blocks are installed on the outer edge face of each threaded shaft (901) in a threaded fit mode, and one ends of the rectangular blocks extend out of the movable groove (801) and are fixedly connected with a sliding plate (10).

4. The height gauge probe connection structure for automobile part machining according to claim 3, characterized in that: a third sliding groove (1001) is formed in the sliding plate (10) in the middle, a plurality of groups of second limiting holes (1002) are formed in the upper end face of the sliding plate (10) at equal intervals, a group of third sliding shafts (11) are fixedly installed in the third sliding groove (1001), a third sliding block (1101) is installed on the outer edge face of each third sliding shaft (11) in a sliding fit mode, the third sliding groove (1001) extends out of the two sides of each third sliding block (1101) and is fixedly connected with a group of U-shaped plates (12), a gauge is installed on the upper end face of each U-shaped plate (12), a third extending plate (1201) is fixedly connected to one side of the upper end face of each U-shaped plate (12), a threaded hole matched with the second limiting hole (1002) is formed in each third extending plate (1201), a sleeve (13) is fixedly connected to the middle of the lower end face of each U-shaped plate (12), and a group of probes (1301), one end of the probe (1301) is provided with a probe.

5. The height gauge probe connection structure for automobile part processing according to claim 1, wherein: the vacuum plate placing device is characterized in that a placing groove (101) is formed in one side of the upper end face of the placing plate (1), supporting legs (2) are fixedly mounted at four corners of the lower end face of the placing plate (1), and vacuum suckers (201) are fixedly connected to the lower end face of each supporting leg (2).

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