CN219216987U - Adjustable sensor support - Google Patents

Abstract

The utility model relates to the technical field of support frames, in particular to an adjustable sensor support, which comprises a support rod, wherein a first sliding device and a second sliding device are arranged on the support rod; the first sliding device is used for driving the second sliding device to move leftwards or rightwards; the second sliding device is used for driving the two sensor brackets which are arranged oppositely to move relatively. The utility model adopts two sets of adjusting devices, so that the application range is wider; the whole coil of material of the material membrane can be moved left and right to rectify the deviation, so that the whole coil of material can be adjusted, the distance between two sensor supports which are oppositely arranged can be adjusted according to the material membrane demands of different widths, the sensor distance can be adjusted, the sensor support is suitable for the material membranes of different widths, the problem that a set of production equipment is required to be configured for each material membrane of single width is solved, and the production cost is greatly reduced; compact structure, simple to operate can adapt to in the many positions of cross cutting equipment.

Description

Adjustable sensor support

Technical Field

The utility model relates to the technical field of supporting frames, in particular to an adjustable sensor bracket.

Background

Circular knife processing is a die cutting method capable of completing processing of multi-layer composite materials in one processing process. At present, the circular knife die cutting machine is developed from a simple three-station to a five-station and a seven-station, and then reaches an eighteen-station at present, so that auxiliary shafts are more and more, and equipment application is more and more flexible. The circular knife die cutting machine is driven by a servo motor and controlled by tension, and the control precision is high. However, along with the development of technology, the precision requirement on die cutting is higher and higher, if the position adjustment of the material film is inaccurate, a great amount of material film is likely to be wasted, but the existing equipment generally only uses the naked eyes of workers to place the position of the coil stock in the feeding or working process, or uses manual correction, the correction effect is poor, and the precision adjustment is extremely inaccurate. Thus, the material film with high precision requirement cannot meet the requirement of producing qualified products. And a set of die cutting equipment can only be suitable for the material film of same width, and application scope is narrow and small, if die cutting is carried out to the material film of different width, need dispose different production equipment, manufacturing cost is high.

Disclosure of Invention

Aiming at the defects, the utility model aims to provide an adjustable sensor bracket, which adopts two sets of adjusting devices, so that the application range is wider; the whole coil of material of the material membrane can be moved left and right to rectify the deviation, so that the whole coil of material can be adjusted, the distance between two sensor supports which are oppositely arranged can be adjusted according to the material membrane demands of different widths, the sensor distance can be adjusted, the sensor support is suitable for the material membranes of different widths, the problem that a set of production equipment is required to be configured for each material membrane of single width is solved, and the production cost is greatly reduced; compact structure, simple to operate can adapt to in the many positions of cross cutting equipment.

In order to achieve the above object, the present utility model provides an adjustable sensor bracket, including a support rod, on which a first sliding device and a second sliding device are disposed;

the first sliding device is connected with the supporting rod and the second sliding device in a sliding way, and the first sliding device is used for driving the second sliding device to move leftwards or rightwards;

the second sliding device is provided with two relatively sliding sensor supports, the two relatively sliding sensor supports are respectively provided with a sensor, a material film is arranged between the two relatively sliding sensor supports, the sensor is used for sensing the position of the material film, and the second sliding device is used for driving the two relatively arranged sensor supports to move relatively.

Preferably, the first sliding device comprises a linear guide rail, a sliding block and a locking block, wherein the sliding block and the locking block are fixedly connected with a second sliding device, and the sliding block and the locking block can drive the second sliding device to slide leftwards or rightwards on the linear guide rail.

Further, one side of the sliding block is provided with a micrometer, and one end of the micrometer is abutted against the sliding block; one side of the locking block and the opposite side of the sliding block are provided with limiting devices, the limiting devices are used for limiting the maximum displacement of the second sliding device, and the locking block is provided with a locking knob A.

Further, the limiting device comprises a limiting seat and a spring, and the spring is connected with the limiting seat and the locking block.

Further, the linear guide rail is arranged on the side wall of the supporting rod, and the sliding block is arranged on the bottom wall of the supporting rod and is in sliding connection with the linear guide rail. The micrometer is fixed at the bottom of the linear guide rail.

Further, a slideway matched with the linear guide rail is arranged on the second sliding device, the second sliding device comprises two moving blocks, one end of one moving block is provided with an adjusting hand wheel, and a locking knob B is arranged on the adjusting hand wheel;

a screw rod is arranged between the two moving blocks, and the screw rod is a positive and negative screw rod.

Further, at least one guide shaft is sleeved in the moving block.

Further, two guide shafts are arranged and are respectively positioned at two sides of the screw rod.

Further, the slideway is arranged on one side of the second sliding device, two sensor brackets capable of sliding relatively are arranged at the top of the second sliding device, one end of the screw rod is connected with a screw rod fixing seat through a screw rod nut, the other end of the screw rod is also connected with another screw rod fixing seat through the screw rod nut, and the adjusting hand wheel penetrates through one screw rod fixing seat to be connected with the screw rod nut.

Further, a pointer is arranged on one side of the sensor support, a graduated scale is arranged above the screw rod, the pointer is used for indicating graduations on the graduated scale and used for displaying the inward or outward moving distance of the sensor support.

The utility model provides an adjustable sensor bracket, which adopts two sets of adjusting devices, so that the application range is wider; the whole coil of material of the material membrane can be moved left and right to rectify the deviation, so that the whole coil of material can be adjusted, the distance between two sensor supports which are oppositely arranged can be adjusted according to the material membrane demands of different widths, the sensor distance can be adjusted, the sensor support is suitable for the material membranes of different widths, the problem that a set of production equipment is required to be configured for each material membrane of single width is solved, and the production cost is greatly reduced; compact structure, simple to operate can adapt to in the many positions of cross cutting equipment.

Drawings

FIG. 1 is a schematic view of the structure of an adjustable sensor holder of the present utility model;

FIG. 2 is an enlarged view of M in FIG. 1;

FIG. 3 is a schematic view of another view angle structure of the adjustable sensor mount of the present utility model;

FIG. 4 is a schematic view of a second slide;

fig. 5 is an enlarged view of N in fig. 4;

the device comprises a 1-supporting rod, a 2-first sliding device, a 3-second sliding device, a 4-sensor bracket, a 5-sensor, a 6-adjusting hand wheel, a 7-micrometer, an 8-locking knob B, a 9-locking knob A, a 10-sliding block, a 11-micrometer fixing seat, a 12-spring, a 13-connecting plate, a 14-graduated scale, a 15-pointer, a 16-linear guide rail, a 31-screw rod, a 32-oilless bushing, a 33-screw rod nut, a 34-guide shaft, a 35-moving block, a 101-locking block and a 111-limiting seat.

Detailed Description

The present utility model will be described in further detail with reference to the following examples in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 1 and 2, the present utility model provides an adjustable sensor support, which comprises a support rod 1, wherein a first sliding device 2 and a second sliding device 3 are arranged on the support rod 1. The first sliding device 2 is connected with the supporting rod 1 and the second sliding device 3 in a sliding way and is used for driving the second sliding device 3 to move leftwards or rightwards; the second sliding device 3 is provided with two sensor supports 4 capable of sliding relatively, the two sensor supports 4 capable of sliding relatively are provided with sensors 5, a material film is arranged between the two sensor supports 4 capable of sliding relatively, the sensors 5 are used for sensing the positions of the material film, and the second sliding device 3 is used for driving the two sensor supports 4 which are arranged relatively to move relatively. One end of the supporting rod 1 is provided with a connecting plate 13 for fixing the adjustable sensor bracket of the utility model at a required position.

The first sliding device 2 comprises a linear guide rail 16, a sliding block 10, a locking block 101, a limiting seat 111 and a micrometer 7, wherein the sliding block 10 and the locking block 101 are fixedly connected with a second sliding device 3, and the sliding block 10 and the locking block 101 can drive the second sliding device 3 to slide leftwards or rightwards on the linear guide rail 16.

One side of the sliding block 10 is provided with a micrometer 7, and one end of the micrometer 7 passes through a micrometer fixing seat 11 to be abutted against the sliding block 10; one side of the locking block 101, which is located at the opposite side of the slider 10, is provided with a limiting means for limiting the maximum displacement of the second slider 3.

The limiting device comprises a limiting seat 111 and a spring 12, and the spring 12 is connected with the limiting seat 111 and the locking block 101.

The locking block 101 is provided with a locking knob A9.

In this embodiment, the linear guide 16 is disposed on a side wall of the support rod 1, and the slider 10 is disposed on a bottom wall of the support rod 1 and slidably connected to the linear guide 16. The micrometer 7 is fixed at the bottom of the linear guide rail 16.

Referring to fig. 3, 4 and 5, the second sliding device 3 is provided with a slideway (not shown) adapted to the linear guide 16. Specifically, the slideway is arranged at one side of the second sliding device 3, and two sensor brackets 4 which can slide relatively are arranged at the top of the second sliding device 3. The second sliding device 3 comprises two moving blocks 35, one end of one moving block 35 is provided with an adjusting hand wheel 6, a screw rod 31 is arranged between the two moving blocks 35, the screw rod 31 is a positive and negative screw rod, one end of the screw rod 31 is connected with a screw rod fixing seat through a screw rod nut 33, the other end of the screw rod 31 is also connected with the other screw rod fixing seat through the screw rod nut 33, and the adjusting hand wheel 6 penetrates through the screw rod fixing seat and is connected with the screw rod nut 33. The adjusting hand wheel 6 is provided with a locking knob B8.

The moving block 35 is sleeved with at least one guide shaft 34 through an oilless bushing 32, and the guide shafts 34 are preferably arranged in two and are respectively positioned on two sides of the screw rod 31.

One side of the sensor support 4 is provided with a pointer 15, a graduated scale 14 is arranged above the screw rod 31, and the pointer 15 is used for indicating graduations on the graduated scale 14 so as to display the inward or outward moving distance.

When the whole coil stock membrane needs to move leftwards and rectify, the second sliding device 3 needs to move leftwards wholly, at the moment, the locking knob A9 is firstly rotated and loosened, the locking block 101 can move, then the micrometer 7 is adjusted according to the requirement, the micrometer 7 pushes the sliding block 10 to move leftwards, the second sliding device 3 and the locking block 101 are driven to move leftwards, the spring 12 is compressed, when moving to a proper position, the micrometer 7 is stopped to be adjusted, at the moment, the locking knob A9 is screwed, and the position of the locking block 101 is fixed.

When the whole coil stock membrane needs to move rightwards and rectify, the second sliding device 3 needs to move rightwards wholly, at the moment, the locking knob A9 is firstly rotated and loosened, so that the locking block 101 can move, then the locking block 101 is retracted according to the regulating micrometer 7, the locking block 101 moves rightwards under the action of the spring 12, and then the second sliding device 3 and the sliding block 10 are driven to move rightwards, when the second sliding device moves to a proper position, the spring 12 is in a normal state or a micro-compression state, the sliding block 10 abuts against the micrometer 7, the movement is stopped, and at the moment, the locking knob A9 is screwed tightly, and the position of the locking block 101 is fixed.

The second sliding device 3 can adjust the distance between the two sensor brackets 4 according to the requirement, so that the distance can be adjusted. When the device is used, according to the requirements of a material film, the locking knob B8 is firstly rotated and loosened, then the adjusting hand wheel 6 is rotated, and further the device is driven to simultaneously move inwards or outwards, and after the distance between the two sensor brackets 4 reaches the required distance, the locking knob B8 is screwed, so that the distance adjustment is realized.

The utility model provides an adjustable sensor bracket which is generally arranged on die cutting equipment such as a circular cutter die cutting machine and the like for left and right movement adjustment of a whole coil of material film, so that the whole coil of material is adjustable and deviation-rectifying; the distance between the two sensor brackets which are oppositely arranged can be adjusted according to the material film requirements of different widths so as to be suitable for the material films of different widths, the problem that one production device is required to be configured for each material film with single width is solved, and the production cost is greatly reduced. Two sets of adjusting devices are adopted, so that the application range is wider; the die-cutting device is compact in structure, convenient to install and capable of being adapted to multiple positions of die-cutting equipment.

Of course, the present utility model is capable of other various embodiments and its several details are capable of modification and variation in light of the present utility model, as will be apparent to those skilled in the art, without departing from the spirit and scope of the utility model as defined in the appended claims.

Claims (10)

1. The adjustable sensor bracket comprises a supporting rod (1) and is characterized in that a first sliding device (2) and a second sliding device (3) are arranged on the supporting rod (1);

the first sliding device (2) is connected with the supporting rod (1) and the second sliding device (3) in a sliding way, and the first sliding device (2) is used for driving the second sliding device (3) to move leftwards or rightwards;

the second sliding device (3) is provided with two sensor supports (4) capable of sliding relatively, the two sensor supports (4) capable of sliding relatively are provided with sensors (5), a material film is arranged between the two sensor supports (4) capable of sliding relatively, the sensors (5) are used for sensing the position of the material film, and the second sliding device (3) is used for driving the two sensor supports (4) arranged relatively to move relatively.

2. The adjustable sensor bracket according to claim 1, wherein the first sliding device (2) comprises a linear guide rail (16), a sliding block (10) and a locking block (101), the sliding block (10) and the locking block (101) are fixedly connected with the second sliding device (3), and the sliding block (10) and the locking block (101) can drive the second sliding device (3) to slide leftwards or rightwards on the linear guide rail (16).

3. The adjustable sensor holder according to claim 2, characterized in that one side of the slider (10) is provided with a micrometer (7), one end of the micrometer (7) being abutted against the slider (10); one side of the locking block (101) and the opposite side of the sliding block (10) are provided with limiting devices, the limiting devices are used for limiting the maximum displacement of the second sliding device (3), and the locking block (101) is provided with a locking knob A (9).

4. An adjustable sensor holder according to claim 3, characterized in that the limiting means comprises a limiting seat (111) and a spring (12), the spring (12) connecting the limiting seat (111) and the locking block (101).

5. An adjustable sensor holder according to claim 3, characterized in that the linear guide (16) is arranged on the side wall of the support bar (1), the slider (10) is arranged on the bottom wall of the support bar (1) and is in sliding connection with the linear guide (16), and the micrometer (7) is fixed at the bottom of the linear guide (16).

6. The adjustable sensor bracket according to claim 1, characterized in that the second sliding device (3) is provided with a slideway which is matched with the linear guide rail (16), the second sliding device (3) comprises two moving blocks (35), one end of one moving block (35) is provided with an adjusting hand wheel (6), and the adjusting hand wheel (6) is provided with a locking knob B (8);

a screw rod (31) is arranged between the two moving blocks (35), and the screw rod (31) is a positive and negative screw rod.

7. The adjustable sensor holder according to claim 6, wherein the moving block (35) is internally provided with at least one guide shaft (34).

8. The adjustable sensor holder according to claim 7, wherein two guide shafts (34) are provided, one on each side of the screw (31).

9. The adjustable sensor support according to claim 7, wherein the slideway is arranged at one side of the second sliding device (3), two sensor supports (4) capable of sliding relatively are arranged at the top of the second sliding device (3), one end of the screw rod (31) is connected with a screw rod fixing seat through a screw rod nut (33), the other end of the screw rod (31) is also connected with another screw rod fixing seat through the screw rod nut (33), and the adjusting hand wheel (6) penetrates through one screw rod fixing seat to be connected with the screw rod nut (33).

10. The adjustable sensor support according to claim 6, characterized in that a pointer (15) is arranged on one side of the sensor support (4), a graduated scale (14) is arranged above the screw rod (31), and the pointer (15) is used for indicating graduations on the graduated scale (14) and displaying the inward or outward moving distance of the sensor support (4).

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