CN220435973U - Fine adjustment type sensor support - Google Patents

Abstract

The utility model discloses a micro-adjusting type sensor bracket, which relates to the field of sensor brackets and comprises a U-shaped plate, two sliding seats and two groups of adjusting components, wherein a chute which is vertically arranged is formed in the U-shaped plate, the two sliding seats are arranged in the U-shaped plate one by one, one side of each sliding seat, which is close to the chute, is provided with a limiting component which is arranged in the chute, an inductive proximity switch is arranged in a mounting hole formed in each sliding seat, the two groups of adjusting components are respectively arranged at the top and the bottom of the U-shaped plate, and the adjusting components are connected with the sliding seats and can adjust the positions of the sliding seats.

Description

Fine adjustment type sensor support

Technical Field

The utility model belongs to the field of sensor supports, and particularly relates to a micro-adjusting type sensor support.

Background

Sensors, in particular inductive proximity switches, are very widely used in industrial plants, mainly as position sensors or motion signal detection, and the fixing of such sensors is generally carried out by fixing the sensor itself to a perforated plate-like part with a nut or directly by screws.

However, in some cases, the inductive proximity switch needs to adjust the position, each time the position is adjusted, the fixed nut needs to be loosened, the inductive proximity switch moves to a proper position and then is fixed, and because the inductive proximity switch is fixed again, the inductive proximity switch has a possible loosening or a small amount of movement, and the inductive proximity switch needs to be adjusted for several times, so that the situation is more troublesome when the number of the inductive proximity switches is more.

To solve this problem we have devised a micro-tuned sensor holder.

Disclosure of Invention

The utility model provides a micro-adjustment type sensor bracket, which aims at solving the problems that when the position of an inductive proximity switch needs to be adjusted, a fixed nut needs to be loosened, the nut moves to a proper position and then is fixed, and because the loose movement amount is possible or small when the nut is fixed again, the adjustment can be performed for a plurality of times, and when the number of the inductive proximity switches is large, the situation is more troublesome.

The utility model solves the technical problems by adopting the scheme that: the utility model provides a fine adjustment formula sensor support, includes U type plate, two seat, two sets of adjusting part that slide, set up the spout of vertical setting on the U type plate, two seat that slide set up in U type plate one by one, and the seat that slides is close to one side of spout is provided with spacing part, and spacing part sets up in the spout, installs inductive proximity switch in the mounting hole that the seat was seted up that slides.

The two groups of adjusting parts are respectively arranged at the top and the bottom of the U-shaped plate, and the adjusting parts are connected with the sliding seat and can adjust the position of the sliding seat.

As a preferable technical scheme of the utility model, the utility model further comprises an L-shaped plate block integrally connected with the U-shaped plate block, and two through holes are formed in the L-shaped plate block.

As a preferable technical scheme of the utility model, the limiting part comprises a shaft pin bolt, wherein the shaft pin bolt is arranged in a round hole formed in the sliding seat, and the outer end of the shaft pin bolt sequentially penetrates through the round hole and the sliding groove and is in threaded connection with a limiting nut.

As a preferable technical scheme of the utility model, the limiting component is a T-shaped sliding block arranged on the rear side surface of the sliding seat, and the outer end of the T-shaped sliding block protrudes out of the sliding groove.

As a preferable technical scheme of the utility model, threaded holes are respectively formed in the top and the bottom of the U-shaped plate, and a rotating hole is formed in a transverse plate of the sliding seat.

As a preferred embodiment of the present utility model, the adjusting member includes an adjusting bolt penetrating through the rotation hole and screwed with the screw hole, and an adjusting nut screwed with the adjusting bolt and contacting with the cross plate of the sliding seat.

As a preferred technical scheme of the utility model, the utility model further comprises a reinforcing nut, wherein the reinforcing nut is in threaded connection with the adjusting bolt and is in contact with the U-shaped plate block.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, the inductive proximity switch is directly fixed on the sliding seat, the positions of the sliding seat and the inductive proximity switch are finely adjusted through the cooperation of the adjusting bolt and the adjusting nut, the movement amount is easier to control, the adjustment is more convenient, the inductive proximity switch is not required to be disassembled and assembled, and the adjustment difficulty is reduced.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic elevational view of the present utility model;

fig. 3 is a schematic top view of the present utility model.

In the figure: 11 U-shaped plate, 12L-shaped plate, 2 sliding grooves, 31 shaft pin bolts, 32 limit nuts, 4 inductance type proximity switches, 5 sliding seats, 61 adjusting bolts, 62 reinforcing nuts and 63 adjusting nuts.

Detailed Description

The utility model will be further described with reference to the drawings and examples.

Referring to fig. 1-3, the present utility model provides a technical solution for a micro-adjusting sensor bracket:

embodiment one:

according to the embodiment shown in fig. 1-3, the sliding seat comprises a U-shaped plate 11, two sliding seats 5 and two groups of adjusting parts, wherein a sliding groove 2 is formed in the U-shaped plate 11, the two sliding seats 5 are arranged in the U-shaped plate 11 one by one, one side, close to the sliding groove 2, of the sliding seat 5 is provided with a limiting part, the limiting part comprises a shaft pin bolt 31, the shaft pin bolt 31 is arranged in a round hole formed in the sliding seat 5, the outer end of the limiting part sequentially penetrates out of the round hole and the sliding groove 2 and is in threaded connection with a limiting nut 32, the sliding seat 5 can be limited through the cooperation of the shaft pin bolt 31 and the limiting nut 32, so that the stability of the sliding seat 5 in the up-down sliding process is ensured, and an inductive proximity switch 4 is arranged in a mounting hole formed in the sliding seat 5.

Screw holes are respectively formed in the top and the bottom of the U-shaped plate 11, rotating holes are formed in the transverse plates of the sliding seat 5, two groups of adjusting components are respectively arranged at the top and the bottom of the U-shaped plate 11, each adjusting component comprises an adjusting bolt 61 and an adjusting nut 63, each adjusting bolt 61 penetrates through the corresponding rotating hole and is in threaded connection with the corresponding screw hole, each adjusting bolt 61 can rotate in the corresponding rotating hole through the corresponding rotating hole, each adjusting bolt 61 can rotate upwards or downwards when rotating, when the adjusting bolt 61 does not rotate, the position of each adjusting bolt 61 can be positioned through the matching of the corresponding screw hole and the corresponding adjusting bolt 61, the adjusting nuts 63 are in threaded connection with the transverse plates of the sliding seat 5, and the positions of the sliding seat 5 can be fixed through the matching of the corresponding adjusting nuts 63 and the bolt caps of the adjusting bolts 61.

The adjusting bolt 61 is further reinforced by the reinforcing nut 62, and the reinforcing nut 62 is in threaded connection with the adjusting bolt 61 and is in contact with the U-shaped plate block 11, so that the adjusting bolt 61 is prevented from being loosened due to vibration.

The U-shaped plate block 11 is integrally connected with the L-shaped plate block 12, and two through holes are formed in the L-shaped plate block 12 so that fixing pieces can penetrate through the through holes to mount and fix the L-shaped plate block 12.

When the micro-adjustment type sensor bracket is particularly used, firstly, a fixing piece passes through a through hole to mount an L-shaped plate block 12 at a proper position, and an inductive proximity switch 4 is mounted on a sliding seat 5;

when the position of the inductive proximity switch 4 needs to be adjusted, the adjustment bolt 61 is rotated, and the positions of the sliding seat 5 and the inductive proximity switch 4 are finely adjusted by matching the adjustment bolt 61 with the adjustment nut 63, so that the inductive proximity switch 4 is adjusted to a proper position.

Embodiment two:

on the basis of the first embodiment, the difference is that the limiting component is a T-shaped sliding block arranged on the rear side surface of the sliding seat 5, and the outer end of the T-shaped sliding block protrudes out of the sliding groove 2.

Claims (7)

1. A micro-adjusting sensor holder, characterized in that: the sliding seat is arranged in the U-shaped plate block one by one, one side, close to the sliding groove, of the sliding seat is provided with a limiting part, the limiting part is arranged in the sliding groove, and an inductive proximity switch is arranged in a mounting hole formed in the sliding seat;

the two groups of adjusting parts are respectively arranged at the top and the bottom of the U-shaped plate, and the adjusting parts are connected with the sliding seat and can adjust the position of the sliding seat.

2. The micro-adjustment sensor holder of claim 1, wherein: the U-shaped plate block is integrally connected with the U-shaped plate block, and two through holes are formed in the L-shaped plate block.

3. The micro-adjustment sensor holder of claim 1, wherein: the limiting part comprises a shaft pin bolt, the shaft pin bolt is arranged in a round hole formed in the sliding seat, and the outer end of the shaft pin bolt sequentially penetrates out of the round hole and the sliding groove and is in threaded connection with a limiting nut.

4. The micro-adjustment sensor holder of claim 1, wherein: the limiting part is a T-shaped sliding block arranged on the rear side surface of the sliding seat, and the outer end of the T-shaped sliding block protrudes out of the sliding groove.

5. The micro-adjustment sensor holder of claim 1, wherein: screw holes are respectively formed in the top and the bottom of the U-shaped plate, and rotary holes are formed in the transverse plate of the sliding seat.

6. The micro-machined sensor holder of claim 5, wherein: the adjusting part comprises an adjusting bolt and an adjusting nut, wherein the adjusting bolt penetrates through the rotating hole and is in threaded connection with the threaded hole, and the adjusting nut is in threaded connection with the adjusting bolt and is in contact with the transverse plate of the sliding seat.

7. The micro-machined sensor holder of claim 6, wherein: the U-shaped plate block is characterized by further comprising a reinforcing nut, wherein the reinforcing nut is in threaded connection with the adjusting bolt and is in contact with the U-shaped plate block.