CN109622346B - Novel array structure of ultrasonic transducer - Google Patents

Abstract

The invention relates to an array structure, in particular to a novel array structure of an ultrasonic transducer, which comprises device supports, a slide rail mechanism I, a slide rail mechanism II, a sliding mechanism, a bolt assembly, an installation mechanism and an adjusting mechanism, wherein the rectangular structure of the ultrasonic transducer can be adjusted by adjusting the number and the sliding positions of a plurality of slide rail mechanisms I and a plurality of slide rail mechanisms II in two sliding waist holes, the rectangular structure of the ultrasonic transducer can be further adjusted by adjusting the number and the positions of a plurality of sliding mechanisms in sliding connection on the plurality of slide rail mechanisms I and the plurality of slide rail mechanisms II, the heights of a plurality of installation mechanisms can be adjusted by adjusting the relative distance between the plurality of sliding mechanisms and the installation mechanism, the heights of the ultrasonic transducers installed on a plurality of installation mechanisms can be adjusted, the ultrasonic transducer can be further adjusted to form a rectangular structure, and the relative distance between two device supports can be adjusted by the adjusting mechanism to further adjust the ultrasonic transducer to form a And (4) a shape structure.

Description

Novel array structure of ultrasonic transducer

Technical Field

The invention relates to an array structure, in particular to a novel array structure of an ultrasonic transducer.

Background

For example, publication No. CN205286396U discloses a novel array structure of ultrasonic transducers, which is characterized in that: the structure comprises a piezoelectric ceramic piece, wherein the piezoelectric ceramic piece is provided with a plurality of cutting arrays, the opening ends of the cutting arrays of the piezoelectric ceramic piece face to a sound absorption block, and each independent array simultaneously comprises a plurality of 'micro array elements' formed by 'shallow cutting'; the utility model has the disadvantage that the ultrasonic transducer can not be adjusted to form different array mechanisms according to the use requirement.

Disclosure of Invention

The invention aims to provide a novel array structure of an ultrasonic transducer, which can adjust and arrange the ultrasonic transducer into different array mechanisms according to different use requirements.

The purpose of the invention is realized by the following technical scheme:

a novel array structure of an ultrasonic transducer comprises a device support, a slide rail mechanism I, a slide rail mechanism II, a sliding mechanism, a bolt assembly, an installation mechanism and an adjusting mechanism, wherein the device support comprises a bottom plate I, supporting legs, a bottom plate II, sliding waist holes and connecting baffles, the supporting legs are fixedly connected to two sides of one end of the bottom plate I, the number of the connecting baffles is two, one ends of the two connecting baffles are fixedly connected to two sides of the bottom plate I respectively, the other ends of the two connecting baffles are fixedly connected to two sides of the bottom plate II respectively, the sliding waist holes are formed between the bottom plate I and the bottom plate II, and the number of the device support is two;

the sliding rail mechanism I comprises a sliding rail I, a sliding insert I, a sliding groove III, a sliding slot I, a sliding groove IV and a sliding block I, one end of the sliding rail I is fixedly connected with the sliding insert I, the sliding rail I and the sliding insert I are both provided with the sliding groove III, the two sides of one end of the sliding rail I are both provided with the sliding slot I, the two sides of the other end of the sliding rail I are both provided with the sliding groove IV, the lower end of the sliding rail I is fixedly connected with the sliding block I, and the sliding block I is connected in a bottom plate II on one side in a;

the sliding rail mechanism II comprises a sliding rail II, sliding insert blocks II, sliding grooves V, sliding slots II, sliding grooves VI and sliding blocks II, the two sides of one end of the sliding rail II are fixedly connected with the sliding insert blocks II, the two sides of the two sliding insert blocks II and the two sides of the sliding rail II are respectively provided with the sliding grooves V, the two sliding insert blocks II are respectively and slidably connected into the two sliding slots I, the two sliding grooves V are respectively communicated with the two sliding grooves IV, one end of the upper side of the sliding rail II is provided with the sliding slot II, the other end of the upper side of the sliding rail II is provided with the sliding groove VI, the sliding insert blocks I are slidably connected into the sliding slots II, the sliding grooves III are communicated with the sliding grooves VI, the lower end of the sliding rail II is fixedly connected with the sliding blocks II, the sliding blocks II are slidably connected into the bottom plate II;

the sliding mechanism comprises two sliding side plates, vertical waist holes, sliding connecting plates, sliding blocks III and sliding blocks IV, the sliding side plates are fixedly connected between the middle ends of the two sliding side plates, the vertical waist holes are formed in the two sliding side plates, the sliding blocks IV are fixedly connected to the lower ends of the inner sides of the two sliding side plates, the sliding blocks III are fixedly connected to the lower ends of the sliding connecting plates, the two sliding blocks IV are respectively connected in the two sliding grooves V in a sliding mode, the sliding blocks III are connected in the sliding grooves III in a sliding mode, and the sliding mechanism is provided with a plurality of sliding mechanisms;

the bolt assembly comprises a plurality of bolts and nuts, the bolts are connected in the vertical waist holes in a sliding mode, the nuts are connected to the bolts through threads, and the number of the bolt assemblies is twice that of the sliding mechanisms;

the installation mechanism comprises two installation side plates, two installation connecting plates, a rotary threaded cylinder, an installation handle, a rotary threaded rod, push plates, push rods and clamping plates, the installation side plates are fixedly connected between the middle ends of the two installation side plates, the lower ends of the two installation side plates are respectively in clearance fit with the two bolts, the inner sides of the two nuts are respectively contacted with the two installation side plates, the two ends of the rotary threaded cylinder are respectively and rotatably connected with the upper ends of the two installation side plates, the middle end of the rotary threaded cylinder is fixedly connected with the installation handle, the two ends of the rotary threaded cylinder are respectively and rotatably connected with the rotary threaded rod through threads, the thread rotating directions of the two rotary threaded rods are opposite, the outer ends of the two rotary threaded rods of the rotary threaded rod are respectively and fixedly connected with the push plates, the two push rods are respectively and slidably connected with the two, the inner ends of the two pushing rods are fixedly connected with clamping plates, and the number of the mounting mechanisms is the same as that of the sliding mechanisms.

As further optimization of the technical scheme, the novel array structure of the ultrasonic transducer further comprises a sliding groove I, a sliding groove II and a spring baffle I, wherein the sliding grooves I are formed in the inner sides of the two bottom plates II, the sliding grooves II are formed in the middle ends of the inner sides of the two bottom plates II, and the spring baffle I is fixedly connected to the middle ends of the lower sides of the two bottom plates II.

As the technical scheme is further optimized, the novel array structure of the ultrasonic transducer further comprises a limiting baffle I, a mounting screw I and a locking screw I, wherein the limiting baffle I is mounted at one end of the sliding rail I through the mounting screw I, the locking screw I is connected to the sliding block I through threads, and the upper end of the locking screw I is attached to the bottom plate II.

As further optimization of the technical scheme, the novel array structure of the ultrasonic transducer further comprises a limiting baffle II, a mounting screw II and a locking screw II, wherein the limiting baffle II is mounted at one end of the sliding rail II through the mounting screw II, the locking screw II is connected to the sliding block II through threads, and the upper end of the sliding block II is attached to the bottom plate II.

As a further optimization of the technical scheme, the novel array structure of the ultrasonic transducer further comprises a limiting spigot, wherein the two sides of the bolt are both provided with the limiting spigots, and the bolt is connected in the vertical waist hole in a sliding manner through the two limiting spigots.

As a further optimization of the technical scheme, the novel array structure of the ultrasonic transducer further comprises an adjusting mechanism, the adjusting mechanism comprises an adjusting plate, an adjusting threaded rod, an adjusting handle, an adjusting threaded block, a pushing connecting rod, a spring baffle II and spring sliding columns, two sides of the adjusting plate are respectively connected in two sliding grooves I in a sliding mode, the upper end of the adjusting threaded rod is rotatably connected onto the adjusting plate, the lower end of the adjusting threaded rod is fixedly connected with the adjusting handle, the adjusting threaded block is connected onto the adjusting threaded rod through threads, two ends of the adjusting threaded block are respectively hinged with the pushing connecting rod, the outer ends of the two pushing connecting rods are respectively hinged onto two bottom plates I, two sides of the lower end of the adjusting plate are respectively fixedly connected with the spring baffle II, the outer ends of the two spring baffle II are respectively fixedly connected with the spring sliding columns, the two spring sliding columns are respectively connected onto the two spring baffle I, all the sleeves are provided with compression springs on the two spring sliding columns, and the compression springs are located between the spring baffle I and the spring baffle II.

The novel array structure of the ultrasonic transducer has the beneficial effects that:

the invention relates to a novel array structure of an ultrasonic transducer, which can adjust the rectangular structure of the ultrasonic transducer by adjusting the number of a plurality of sliding rail mechanisms I and a plurality of sliding rail mechanisms II and the sliding positions in two sliding waist holes, further adjust the rectangular structure of the ultrasonic transducer by adjusting the number and the positions of a plurality of sliding mechanisms which are in sliding connection on the plurality of sliding rail mechanisms I and the plurality of sliding rail mechanisms II, adjust the heights of a plurality of mounting mechanisms by adjusting the relative distances between the plurality of sliding mechanisms and the mounting mechanisms, adjust the heights of the ultrasonic transducers mounted on the plurality of mounting mechanisms, further adjust the ultrasonic transducer to form the rectangular structure, and further adjust the relative distance between two device brackets by adjusting the adjusting mechanisms to further adjust the ultrasonic transducer to form the rectangular structure.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic diagram of the overall structure of a novel array structure of an ultrasonic transducer of the present invention;

FIG. 2 is a schematic diagram of the overall structure of the novel array structure of the ultrasonic transducer of the present invention;

FIG. 3 is a first schematic view of the device of the present invention;

FIG. 4 is a second schematic view of the device of the present invention;

FIG. 5 is a first schematic structural diagram of a slide rail mechanism I according to the present invention;

FIG. 6 is a schematic structural diagram II of the slide rail mechanism I of the present invention;

FIG. 7 is a first schematic structural diagram of a sliding rail mechanism II according to the present invention;

FIG. 8 is a second structural schematic view of a slide rail mechanism II according to the present invention;

FIG. 9 is a schematic view of the sliding mechanism of the present invention;

FIG. 10 is a schematic view of the bolt assembly of the present invention;

FIG. 11 is a schematic structural view of the mounting mechanism of the present invention;

FIG. 12 is a cross-sectional structural schematic view of the mounting mechanism of the present invention;

FIG. 13 is a schematic view of the adjustment mechanism of the present invention;

fig. 14 is a schematic cross-sectional view of the adjustment mechanism of the present invention.

In the figure: a device holder 1; a base plate I1-1; supporting legs 1-2; a bottom plate II 1-3; 1-4 of a sliding waist hole; connecting baffle plates 1-5; 1-6 sliding grooves; sliding grooves II 1-7; 1-8 parts of a spring baffle plate; a slide rail mechanism I2; a slide rail I2-1; a sliding insertion block I2-2; 2-3 of a sliding groove III; a sliding slot I2-4; 2-5 of a sliding groove IV; limiting baffles I2-6; mounting screws I2-7; 2-8 sliding blocks; locking screws I2-9; a slide rail mechanism II 3; a sliding rail II 3-1; a sliding insert block II 3-2; a sliding groove V3-3; a sliding slot II 3-4; 3-5 of a sliding groove VI; a limiting baffle II 3-6; mounting screws II 3-7; 3-8 of a sliding block II; locking screws II 3-9; a slide mechanism 4; a sliding side plate 4-1; 4-2 of vertical waist holes; 4-3 of a sliding connecting plate; 4-4 of a sliding block III; 4-5 of a sliding block IV; a bolt assembly 5; 5-1 of a bolt; 5-2 parts of a nut; 5-3 of a limiting spigot; an installation mechanism 6; installing a side plate 6-1; mounting a connecting plate 6-2; rotating the threaded cylinder 6-3; installing a handle 6-4; rotating the threaded rod 6-5; 6-6 of a push plate; 6-7 of a push rod; 6-8 of clamping plate; an adjusting mechanism 7; an adjusting plate 7-1; adjusting the threaded rod 7-2; 7-3 of an adjusting handle; adjusting the thread block 7-4; pushing a connecting rod 7-5; 7-6 parts of a spring baffle plate; spring slide posts 7-7.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Before describing the embodiments, to avoid repetitive language, it is explained that the "fixed connection" described below may be: the fixing device is fixed through modes such as bolt connection, welding and rivet connection, and technicians in the field can select different fixing and connecting modes according to different application scenes, and the fixing device is mainly used for fixing two parts.

The first embodiment is as follows:

the following describes the present embodiment with reference to fig. 1 to 14, a novel array structure of an ultrasonic transducer, which includes a device support 1, a sliding rail mechanism i 2, a sliding rail mechanism ii 3, a sliding mechanism 4, a bolt assembly 5, a mounting mechanism 6, and an adjusting mechanism 7, wherein a rectangular structure of the ultrasonic transducer can be adjusted by adjusting the number of a plurality of sliding rail mechanisms i 2 and a plurality of sliding rail mechanisms ii 3 and the sliding positions in two sliding waist holes 1 to 4, the rectangular structure of the ultrasonic transducer can be further adjusted by adjusting the number and positions of a plurality of sliding mechanisms 4 slidably connected to the plurality of sliding rail mechanisms i 2 and the plurality of sliding rail mechanisms ii 3, the height of a plurality of mounting mechanisms 6 can be adjusted by adjusting the relative distance between the plurality of sliding mechanisms 4 and the mounting mechanism 6, the height of the ultrasonic transducers mounted on a plurality of mounting mechanisms 6 can be adjusted, and the ultrasonic transducer can be further adjusted to form a rectangular structure, the ultrasonic transducer is further adjusted to form a rectangular structure by adjusting the relative distance between the two device brackets 1 through the adjusting mechanism 7.

The device support 1 comprises a base plate I1-1, supporting legs 1-2, a base plate II 1-3, sliding waist holes 1-4 and connecting baffle plates 1-5, wherein the supporting legs 1-2 are fixedly connected to two sides of one end of the base plate I1-1, the number of the connecting baffle plates 1-5 is two, one ends of the two connecting baffle plates 1-5 are fixedly connected to two sides of the base plate I1-1 respectively, the other ends of the two connecting baffle plates 1-5 are fixedly connected to two sides of the base plate II 1-3 respectively, the sliding waist holes 1-4 are formed between the base plate I1-1 and the base plate II 1-3, and the number of the device support 1 is two;

the sliding rail mechanism I2 comprises a sliding rail I2-1, a sliding insertion block I2-2, a sliding groove III 2-3, a sliding insertion groove I2-4, a sliding groove IV 2-5 and a sliding block I2-8, wherein one end of the sliding rail I2-1 is fixedly connected with the sliding insertion block I2-2, the sliding rail I2-1 and the sliding insertion block I2-2 are respectively provided with the sliding groove III 2-3, two sides of one end of the sliding rail I2-1 are respectively provided with the sliding insertion groove I2-4, two sides of the other end of the sliding rail I2-1 are respectively provided with the sliding groove IV 2-5, the lower end of the sliding rail I2-1 is fixedly connected with the sliding block I2-8, and the sliding block I2-8 is slidably connected in a bottom plate II 1-3;

the sliding rail mechanism II 3 comprises a sliding rail II 3-1, sliding insert blocks II 3-2, sliding grooves V3-3, sliding slots II 3-4, sliding grooves VI 3-5 and sliding blocks II 3-8, wherein the sliding insert blocks II 3-2 are fixedly connected to two sides of one end of the sliding rail II 3-1, the sliding grooves V3-3 are arranged on two sides of the two sliding insert blocks II 3-2 and the sliding rail II 3-1, the two sliding insert blocks II 3-2 are respectively connected in the two sliding slots I2-4 in a sliding mode, the two sliding grooves V3-3 are respectively communicated with the two sliding grooves IV 2-5, the sliding slot II 3-4 is arranged at one end of the upper side of the sliding rail II 3-1, the sliding groove VI 3-5 is arranged at the other end of the upper side of the sliding rail II 3-1, the sliding insert block I2-2 is connected in the sliding slot II 3-4 in a sliding mode, the sliding grooves III 2-3 are communicated with the sliding grooves VI 3-5, the lower ends of the sliding rails II 3-1 are fixedly connected with sliding blocks II 3-8, the sliding blocks II 3-8 are connected in the bottom plate II 1-3 on the other side in a sliding mode, and a plurality of sliding rail mechanisms I2 and a plurality of sliding rail mechanisms II 3 are arranged in pairs;

the sliding mechanism 4 comprises a sliding side plate 4-1 and a vertical waist hole 4-2, the sliding mechanism comprises two sliding side plates 4-3, two sliding blocks III-4 and two sliding blocks IV 4-5, wherein the two sliding side plates 4-1 are fixedly connected with the sliding connecting plates 4-3 between the middle ends of the two sliding side plates 4-1, the two sliding side plates 4-1 are respectively provided with a vertical waist hole 4-2, the lower ends of the inner sides of the two sliding side plates 4-1 are respectively fixedly connected with the sliding blocks IV 4-5, the lower end of the sliding connecting plate 4-3 is fixedly connected with the sliding blocks III 4-4, the two sliding blocks IV 4-5 are respectively and slidably connected into the two sliding grooves V3-3, the sliding blocks III 4-4 are slidably connected into the sliding grooves III 2-3, and a plurality of sliding mechanisms 4 are arranged;

the bolt assembly 5 comprises a bolt 5-1 and a nut 5-2, the bolt 5-1 is slidably connected in the vertical waist hole 4-2, the nut 5-2 is connected on the bolt 5-1 through threads, the number of the bolt assemblies 5 is two times that of the sliding mechanisms 4;

the installation mechanism 6 comprises two installation side plates 6-1, two installation connecting plates 6-2, two rotating threaded cylinders 6-3, two installation handles 6-4, two rotating threaded rods 6-5, two pushing plates 6-6, two pushing rods 6-7 and two clamping plates 6-8, the installation side plates 6-1 are fixedly connected with the installation connecting plates 6-2 between the middle ends of the two installation side plates 6-1, the lower ends of the two installation side plates 6-1 are respectively in clearance fit with the two bolts 5-1, the inner sides of the two nuts 5-2 are respectively contacted with the two installation side plates 6-1, the two ends of the rotating threaded cylinders 6-3 are respectively rotatably connected with the upper ends of the two installation side plates 6-1, the middle ends of the rotating threaded cylinders 6-3 are fixedly connected with the installation handles 6-4, two ends of the rotary threaded cylinder 6-3 are respectively connected with rotary threaded rods 6-5 through threads, the thread turning directions of the two rotary threaded rods 6-5 are opposite, the outer ends of the two rotary threaded rods 6-5 of the rotary threaded rods 6-5 are respectively fixedly connected with push plates 6-6, the two push plates 6-6 are respectively fixedly connected with push rods 6-7, the two push rods 6-7 are respectively connected with the two installation side plates 6-1 in a sliding manner, the inner ends of the two push rods 6-7 are respectively fixedly connected with clamping plates 6-8, and the installation mechanisms 6 and the sliding mechanisms 4 are the same in number;

when in use, the ultrasonic transducer is placed between the two clamping plates 6-8, the installation handle 6-4 is rotated to ensure that the installation handle 6-4 rotates by taking the axis of the rotary threaded cylinder 6-3 as the center, the installation handle 6-4 drives the rotary threaded cylinder 6-3 to rotate by taking the axis of the rotary threaded cylinder 6-3 as the center, the rotary threaded cylinder 6-3 drives the two rotary threaded rods 6-5 at two sides to move through threads, the thread turning directions on the two rotary threaded rods 6-5 are opposite, the two rotary threaded rods 6-5 approach or separate from each other when rotating, the two rotary threaded rods 6-5 approach each other to drive the two pushing plates 6-6 to approach each other, the two pushing plates 6-6 respectively drive the two pushing rods 6-7 to approach each other, the two pushing rods 6-7 respectively drive the two clamping plates 6-8 to approach each other, and the ultrasonic transducer is clamped; the rectangular structure of the ultrasonic transducer can be further adjusted by adjusting the number and the positions of the sliding mechanisms 4 which are in sliding connection with the sliding rail mechanisms I2 and II 3, the heights of the installation mechanisms 6 can be adjusted by adjusting the relative distances between the sliding mechanisms 4 and the installation mechanisms 6, the heights of the ultrasonic transducers installed on the installation mechanisms 6 can be adjusted, the ultrasonic transducer can be further adjusted to form the rectangular structure, and the relative distance between the two device supports 1 can be adjusted by the adjusting mechanism 7 to further adjust the ultrasonic transducer to form the rectangular structure.

The second embodiment is as follows:

the device bracket 1 further comprises sliding grooves I1-6, sliding grooves II 1-7 and spring baffles I1-8, the sliding grooves I1-6 are arranged on the inner sides of the two bottom plates II 1-3, the sliding grooves II 1-7 are arranged at the middle ends of the inner sides of the two bottom plates II 1-3, and the spring baffles I1-8 are fixedly connected to the middle ends of the lower sides of the two bottom plates II 1-3.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 14, and the embodiment further describes the second embodiment, the slide rail mechanism i 2 further includes a limit baffle i 2-6, a mounting screw i 2-7 and a locking screw i 2-9, the limit baffle i 2-6 is mounted at one end of the slide rail i 2-1 through the mounting screw i 2-7, the locking screw i 2-9 is connected to the sliding block i 2-8 through a thread, and the upper end of the locking screw i 2-9 is attached to the bottom plate ii 1-3;

when the position of the sliding rail I2-1 needs to be fixed, the locking screw I2-9 is rotated to enable the locking screw I2-9 to rotate by taking the axis of the locking screw I2-9 as the center, the locking screw I2-9 extrudes the bottom plate II 1-3 through a thread pair, and the position of the sliding rail I2-1 is fixed.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1-14, the sliding rail mechanism ii 3 further includes a limit baffle ii 3-6, a mounting screw ii 3-7 and a locking screw ii 3-9, the limit baffle ii 3-6 is mounted at one end of the sliding rail ii 3-1 through the mounting screw ii 3-7, the locking screw ii 3-9 is connected to the sliding block ii 3-8 through a screw thread, and the upper end of the sliding block ii 3-8 is attached to the bottom plate ii 1-3;

when the position of the sliding rail II 3-1 needs to be fixed, the locking screw II 3-9 is rotated, so that the locking screw II 3-9 rotates by taking the axis of the locking screw II 3-9 as the center, the locking screw II 3-9 extrudes the bottom plate II 1-3 through a thread pair, and the position of the sliding rail II 3-1 is fixed.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1-14, the bolt assembly 5 further includes a limiting spigot 5-3, both sides of the bolt 5-1 are provided with the limiting spigot 5-3, and the bolt 5-1 is slidably connected in the vertical waist hole 4-2 through the two limiting spigots 5-3;

when the bolt assembly 5 is installed and the relative height between the fixed installation mechanism 6 and the sliding mechanism 4 is fixed, the nut 5-2 is rotated to enable the nut 5-2 to rotate around the axis of the bolt 5-1, and the nut 5-2 extrudes the installation side plate 6-1 corresponding to the nut 5-2, so that the relative height between the fixed installation mechanism 6 and the sliding mechanism 4 is fixed.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 14, and the fifth embodiment is further described, the novel array structure of the ultrasonic transducer further includes an adjusting mechanism 7, the adjusting mechanism 7 includes an adjusting plate 7-1, an adjusting threaded rod 7-2, an adjusting handle 7-3, an adjusting threaded block 7-4, a push connecting rod 7-5, a spring baffle plate ii 7-6, and a spring sliding column 7-7, two sides of the adjusting plate 7-1 are respectively slidably connected in two sliding grooves i 1-6, an upper end of the adjusting threaded rod 7-2 is rotatably connected to the adjusting plate 7-1, a lower end of the adjusting threaded rod 7-2 is fixedly connected with the adjusting handle 7-3, the adjusting threaded block 7-4 is connected to the adjusting threaded rod 7-2 by a thread, two ends of the adjusting threaded block 7-4 are both hinged with the push connecting rod 7-5, the outer ends of the two pushing connecting rods 7-5 are respectively hinged to the two bottom plates I1-1, two sides of the lower end of the adjusting plate 7-1 are fixedly connected with spring baffle plates II 7-6, the outer ends of the two spring baffle plates II 7-6 are respectively fixedly connected with spring sliding columns 7-7, the two spring sliding columns 7-7 are respectively connected to the two spring baffle plates I1-8 in a sliding mode, compression springs are sleeved on the two spring sliding columns 7-7, and the compression springs are located between the spring baffle plates I1-8 and the spring baffle plates II 7-6;

when the distance between the device supports 1 needs to be adjusted, when the adjusting handle 7-3 is rotated, the adjusting handle 7-3 rotates by taking the axis of the adjusting threaded rod 7-2 as the center, the adjusting handle 7-3 drives the adjusting threaded rod 7-2 to rotate by taking the axis of the adjusting threaded rod 7-2 as the center, the adjusting threaded rod 7-2 pushes the adjusting threaded block 7-4 to move in the axis direction of the adjusting threaded rod 7-2 through threads, the adjusting threaded block 7-4 pushes the inner sides of the two pushing connecting rods 7-5 to move upwards, the outer ends of the two pushing connecting rods 7-5 are far away from each other, and the outer ends of the two pushing connecting rods 7-5 respectively push the two device supports 1 to be far away from each other.

The invention relates to a novel array structure of an ultrasonic transducer, which has the working principle that: when in use, the ultrasonic transducer is placed between the two clamping plates 6-8, the installation handle 6-4 is rotated to ensure that the installation handle 6-4 rotates by taking the axis of the rotary threaded cylinder 6-3 as the center, the installation handle 6-4 drives the rotary threaded cylinder 6-3 to rotate by taking the axis of the rotary threaded cylinder 6-3 as the center, the rotary threaded cylinder 6-3 drives the two rotary threaded rods 6-5 at two sides to move through threads, the thread turning directions on the two rotary threaded rods 6-5 are opposite, the two rotary threaded rods 6-5 approach or separate from each other when rotating, the two rotary threaded rods 6-5 approach each other to drive the two pushing plates 6-6 to approach each other, the two pushing plates 6-6 respectively drive the two pushing rods 6-7 to approach each other, the two pushing rods 6-7 respectively drive the two clamping plates 6-8 to approach each other, and the ultrasonic transducer is clamped; the rectangular structure of the ultrasonic transducer can be further adjusted by adjusting the number and the positions of the sliding mechanisms 4 which are in sliding connection with the sliding rail mechanisms I2 and the sliding rail mechanisms II 3, the heights of the installation mechanisms 6 can be adjusted by adjusting the relative distances between the sliding mechanisms 4 and the installation mechanisms 6, the heights of the ultrasonic transducers installed on the installation mechanisms 6 can be adjusted, the rectangular structure can be further formed by adjusting the ultrasonic transducer, and the rectangular structure can be further formed by adjusting the relative distance between the two device brackets 1 by adjusting the adjusting mechanism 7; when the position of the sliding rail I2-1 needs to be fixed, the locking screw I2-9 is rotated, so that the locking screw I2-9 rotates by taking the axis of the locking screw I2-9 as the center, the locking screw I2-9 extrudes the bottom plate II 1-3 through a thread pair, and the position of the sliding rail I2-1 is fixed; when the position of the sliding rail II 3-1 needs to be fixed, the locking screw II 3-9 is rotated, so that the locking screw II 3-9 rotates by taking the axis of the locking screw II 3-9 as the center, the locking screw II 3-9 extrudes the bottom plate II 1-3 through a thread pair, and the position of the sliding rail II 3-1 is fixed; when the bolt assembly 5 is installed and the relative height between the fixed installation mechanism 6 and the sliding mechanism 4 is fixed, the nut 5-2 is rotated to enable the nut 5-2 to rotate by taking the axis of the bolt 5-1 as the center, and the nut 5-2 extrudes the installation side plate 6-1 corresponding to the nut 5-2, so that the relative height between the fixed installation mechanism 6 and the sliding mechanism 4 is fixed; when the distance between the device supports 1 needs to be adjusted, when the adjusting handle 7-3 is rotated, the adjusting handle 7-3 rotates by taking the axis of the adjusting threaded rod 7-2 as the center, the adjusting handle 7-3 drives the adjusting threaded rod 7-2 to rotate by taking the axis of the adjusting threaded rod 7-2 as the center, the adjusting threaded rod 7-2 pushes the adjusting threaded block 7-4 to move in the axis direction of the adjusting threaded rod 7-2 through threads, the adjusting threaded block 7-4 pushes the inner sides of the two pushing connecting rods 7-5 to move upwards, the outer ends of the two pushing connecting rods 7-5 are far away from each other, and the outer ends of the two pushing connecting rods 7-5 respectively push the two device supports 1 to be far away from each other.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (6)

1. The utility model provides an ultrasonic transducer's novel array structure, includes device support (1), slide rail mechanism I (2), slide rail mechanism II (3), slide mechanism (4), bolt assembly (5), installation mechanism (6) and guiding mechanism (7), its characterized in that: the device support (1) comprises a base plate I (1-1), supporting feet (1-2), a base plate II (1-3), sliding waist holes (1-4) and connecting baffle plates (1-5), wherein the two sides of one end of the base plate I (1-1) are fixedly connected with the supporting feet (1-2), the number of the connecting baffle plates (1-5) is two, one ends of the two connecting baffle plates (1-5) are respectively and fixedly connected to the two sides of the base plate I (1-1), the other ends of the two connecting baffle plates (1-5) are respectively and fixedly connected to the two sides of the base plate II (1-3), the sliding waist holes (1-4) are formed between the base plate I (1-1) and the base plate II (1-3), and the number of the device support (1) is two;

the sliding rail mechanism I (2) comprises a sliding rail I (2-1), a sliding insertion block I (2-2), a sliding groove III (2-3), a sliding slot I (2-4), a sliding groove IV (2-5) and a sliding block I (2-8), one end of a sliding rail I (2-1) is fixedly connected with a sliding insert I (2-2), sliding grooves III (2-3) are formed in the sliding rail I (2-1) and the sliding insert I (2-2), sliding slots I (2-4) are formed in two sides of one end of the sliding rail I (2-1), sliding grooves IV (2-5) are formed in two sides of the other end of the sliding rail I (2-1), the lower end of the sliding rail I (2-1) is fixedly connected with a sliding block I (2-8), and the sliding block I (2-8) is connected into a bottom plate II (1-3) on one side in a sliding mode;

the sliding rail mechanism II (3) comprises a sliding rail II (3-1), sliding insert blocks II (3-2), sliding grooves V (3-3), sliding slots II (3-4), sliding grooves VI (3-5) and sliding blocks II (3-8), the sliding insert blocks II (3-2) are fixedly connected to two sides of one end of the sliding rail II (3-1), the sliding grooves V (3-3) are arranged on two sides of the two sliding insert blocks II (3-2) and the sliding rail II (3-1), the two sliding insert blocks II (3-2) are respectively connected in the two sliding slots I (2-4) in a sliding mode, the two sliding grooves V (3-3) are respectively communicated with the two sliding grooves IV (2-5), the sliding slot II (3-4) is arranged at one end of the upper side of the sliding rail II (3-1), the other end of the upper side of the sliding rail II (3-1) is provided with a sliding groove VI (3-5), a sliding insert block I (2-2) is connected in the sliding groove II (3-4) in a sliding mode, a sliding groove III (2-3) is communicated with the sliding groove VI (3-5), the lower end of the sliding rail II (3-1) is fixedly connected with a sliding block II (3-8), the sliding block II (3-8) is connected in a bottom plate II (1-3) on the other side in a sliding mode, and a plurality of sliding rail mechanisms I (2) and a plurality of sliding rail mechanisms II (3) are arranged in pairs;

the sliding mechanism (4) comprises two sliding side plates (4-1), two vertical waist holes (4-2), two sliding connecting plates (4-3), two sliding blocks III (4-4) and two sliding blocks IV (4-5), the sliding side plates (4-1) are fixedly connected with the sliding connecting plates (4-3) between the middle ends of the two sliding side plates (4-1), the two sliding side plates (4-1) are respectively provided with the vertical waist holes (4-2), the lower ends of the inner sides of the two sliding side plates (4-1) are respectively fixedly connected with the sliding blocks IV (4-5), the lower ends of the sliding connecting plates (4-3) are respectively fixedly connected with the sliding blocks III (4-4), the two sliding blocks IV (4-5) are respectively connected in the two sliding grooves V (3-3), the sliding blocks III (4-4) are connected in the sliding grooves III (2-3) in a sliding mode, and a plurality of sliding mechanisms (4) are arranged;

the bolt assembly (5) comprises a bolt (5-1) and a nut (5-2), the bolt (5-1) is connected in the vertical waist hole (4-2) in a sliding mode, the nut (5-2) is connected to the bolt (5-1) through threads, the number of the bolt assemblies (5) is two times that of the sliding mechanisms (4);

the mounting mechanism (6) comprises two mounting side plates (6-1), two mounting connecting plates (6-2), two rotating threaded cylinders (6-3), two mounting handles (6-4), two rotating threaded rods (6-5), two push plates (6-6), two push rods (6-7) and two clamping plates (6-8), the mounting connecting plates (6-2) are fixedly connected between the middle ends of the two mounting side plates (6-1), the lower ends of the two mounting side plates (6-1) are respectively in clearance fit with the two bolts (5-1), the inner sides of the two nuts (5-2) are respectively contacted with the two mounting side plates (6-1), the two ends of the rotating threaded cylinders (6-3) are respectively rotatably connected to the upper ends of the two mounting side plates (6-1), the middle end of the rotary threaded cylinder (6-3) is fixedly connected with an installation handle (6-4), two ends of the rotary threaded cylinder (6-3) are respectively connected with rotary threaded rods (6-5) through threads, the thread turning directions of the two rotary threaded rods (6-5) are opposite, the outer ends of the two rotary threaded rods (6-5) of the rotary threaded rods (6-5) are respectively and fixedly connected with pushing plates (6-6), the two pushing plates (6-6) are respectively and fixedly connected with pushing rods (6-7), the two pushing rods (6-7) are respectively and slidably connected onto the two installation side plates (6-1), the inner ends of the two pushing rods (6-7) are respectively and fixedly connected with clamping plates (6-8), and the installation mechanisms (6) and the sliding mechanisms (4) are the same in number;

when in use, the ultrasonic transducer is placed between the two clamping plates (6-8).

2. The novel array structure of ultrasonic transducer according to claim 1, characterized in that: the device support (1) further comprises sliding grooves I (1-6), sliding grooves II (1-7) and spring baffles I (1-8), the sliding grooves I (1-6) are arranged on the inner sides of the two bottom plates II (1-3), the sliding grooves II (1-7) are arranged at the middle ends of the inner sides of the two bottom plates II (1-3), and the spring baffles I (1-8) are fixedly connected to the middle ends of the lower sides of the two bottom plates II (1-3).

3. The novel array structure of ultrasonic transducer according to claim 2, characterized in that: slide rail mechanism I (2) still include limit baffle I (2-6), mounting screw I (2-7) and locking screw I (2-9), and limit baffle I (2-6) are installed in the one end of slide rail I (2-1) through mounting screw I (2-7), and locking screw I (2-9) are through threaded connection on sliding block I (2-8), and the upper end and the bottom plate II (1-3) laminating of locking screw I (2-9).

4. The novel array structure of ultrasonic transducer according to claim 3, characterized in that: the sliding rail mechanism II (3) further comprises a limiting baffle II (3-6), a mounting screw II (3-7) and a locking screw II (3-9), the limiting baffle II (3-6) is mounted at one end of the sliding rail II (3-1) through the mounting screw II (3-7), the locking screw II (3-9) is connected to the sliding block II (3-8) through threads, and the upper end of the sliding block II (3-8) is attached to the bottom plate II (1-3).

5. The novel array structure of ultrasonic transducer according to claim 4, wherein: the bolt assembly (5) further comprises limiting rabbets (5-3), the two sides of the bolt (5-1) are respectively provided with the limiting rabbets (5-3), and the bolt (5-1) is connected in the vertical waist hole (4-2) in a sliding mode through the two limiting rabbets (5-3).

6. The novel array structure of ultrasonic transducer according to claim 5, characterized in that: the novel array structure of the ultrasonic transducer further comprises an adjusting mechanism (7), the adjusting mechanism (7) comprises an adjusting plate (7-1), an adjusting threaded rod (7-2), an adjusting handle (7-3), an adjusting threaded block (7-4), a push connecting rod (7-5), a spring baffle plate II (7-6) and a spring sliding column (7-7), two sides of the adjusting plate (7-1) are respectively connected in the two sliding grooves I (1-6) in a sliding mode, the upper end of the adjusting threaded rod (7-2) is rotatably connected to the adjusting plate (7-1), the lower end of the adjusting threaded rod (7-2) is fixedly connected with the adjusting handle (7-3), the adjusting threaded block (7-4) is connected to the adjusting threaded rod (7-2) through threads, the two ends of the adjusting threaded block (7-4) are hinged to the push connecting rod (7-5), the outer ends of the two pushing connecting rods (7-5) are hinged to the two bottom plates I (1-1) respectively, spring baffle plates II (7-6) are fixedly connected to the two sides of the lower end of the adjusting plate (7-1), spring sliding columns (7-7) are fixedly connected to the outer ends of the two spring baffle plates II (7-6), the two spring sliding columns (7-7) are slidably connected to the two spring baffle plates I (1-8) respectively, compression springs are sleeved on the two spring sliding columns (7-7) respectively and located between the spring baffle plates I (1-8) and the spring baffle plates II (7-6).

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