CN211049519U - Micro-energy shock wave therapeutic instrument fixing support - Google Patents

Abstract

The utility model discloses a little energy shock wave treatment instrument fixed bolster, including a supporting bench, treatment mechanism is installed to one side of brace table, and treatment mechanism's inside including first axis of rotation, one side of first axis of rotation is connected with straight type support, and is fixed connection between the opposite side of first axis of rotation and the brace table, the first parallel beam of top fixedly connected with of straight type support, and the both sides of first parallel beam gomphosis respectively are connected with first spout, first parallel beam's outside cup joints and is connected with first movable cross beam, and the first shock wave probe of first movable cross beam's bottom fixedly connected with. The utility model discloses in, through drawing to rise or shrink first movable cross beam and second movable cross beam, the position of steerable shock wave probe makes things convenient for patient to lie and goes into testing platform, can adjust the angle of shock wave probe through rotating first axis of rotation, ensures the needs that the treatment instrument angle need be adjusted to the treatment in-process.

Description

Micro-energy shock wave therapeutic instrument fixing support

Technical Field

The utility model relates to a clinical medicine field especially relates to a micro-energy shock wave therapeutic instrument fixed bolster.

Background

The micro-energy shock wave therapeutic apparatus can be used for external shock wave lithotripsy, the external shock wave lithotripsy technology is applied to the fields of orthopedics and rehabilitation physiotherapy at the end of the eighties of the twentieth century, and shock waves are a novel treatment mode between conservative therapy and operative therapy.

The treatment structure part of current micro-energy shock wave therapeutic apparatus is fixed, can only let patient's carelessness wing lie flat and get into, get off also so, and testing platform adopts fixed mode moreover, and this is very inconvenient to the people of height difference, and testing platform of general micro-energy shock wave therapeutic apparatus is than higher, but testing platform about special personnel such as disabled person is just very inconvenient, a micro-energy shock wave therapeutic apparatus fixed bolster that so proposed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem that the existing micro-energy shock wave therapeutic apparatus fixing support does not have a good angle from the patient, can not make things convenient for the micro-energy shock wave therapeutic apparatus from top to bottom of the patient well, and therefore the micro-energy shock wave therapeutic apparatus fixing support is provided.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

A micro-energy shock wave therapeutic instrument fixing support comprises a support table, a therapeutic mechanism is mounted on one side of the support table, a first rotating shaft is arranged inside the therapeutic mechanism, a straight support is connected to one side of the first rotating shaft, the other side of the first rotating shaft is fixedly connected with the support table, a first parallel cross beam is fixedly connected to the top end of the straight support, first sliding grooves are respectively connected to two sides of the first parallel cross beam in an embedded mode, a first moving cross beam is connected to the outer portion of the first parallel cross beam in a sleeved mode, a first shock wave probe is fixedly connected to the bottom end of the first moving cross beam, first sliding blocks are respectively connected to two sides of the inner wall of the first moving cross beam, the first sliding blocks are connected with the first sliding grooves in a sleeved mode, a second parallel cross beam is fixedly connected to the bottom end of the straight support, and second sliding grooves are respectively connected to two sides of the second parallel cross beam, the outer portion of the second parallel cross beam is connected with a second movable cross beam in a sleeved mode, a second shock wave probe is fixedly connected to the top end of the second movable cross beam, second sliding blocks are connected to two sides of the inner wall of the second movable cross beam respectively, the second sliding blocks are connected with second sliding grooves in a sleeved mode, a detection platform is installed above the second shock wave probe, and a lifting base is installed at the bottom end of the detection platform.

As a further description of the above technical solution:

The straight type support forms a rotating structure through the space between the first rotating shaft and the support table, the first movable cross beam forms a sliding structure through the space between the first sliding block and the first sliding groove, and the second movable cross beam forms a sliding structure through the space between the second sliding block and the second sliding groove.

As a further description of the above technical solution:

The inside first slide that is included of testing platform, and the both sides of first slide gomphosis respectively are connected with the third spout, the internal connection of third spout has the gyro wheel, and one side fixedly connected with second axis of rotation of gyro wheel, the outside of first slide cup joints and is connected with the second slide, and the inner wall both sides of second slide respectively with the second axis of rotation between be fixed connection, one side fixedly connected with of first slide draws the handle.

As a further description of the above technical solution:

The third sliding groove is connected with the roller in a sleeved mode, and the third sliding groove is of a rolling structure formed between the roller and the second rotating shaft.

As a further description of the above technical solution:

The lifting base is internally provided with a first sleeve, the positions of the top end of the interior of the first sleeve, which are close to the two sides of the inner wall, are respectively connected with a fourth chute in an embedded manner, the interior of the fourth chute is respectively connected with a fourth slider in a sleeved manner, the bottom end of the fourth slider is respectively connected with a first supporting plate, one side of the first supporting plate is connected with a third rotating shaft, the exterior of the first sleeve is connected with a second sleeve in a sleeved manner, the positions of the bottom end of the second sleeve, which are close to the two sides of the inner wall, are respectively fixedly connected with a second supporting plate, one side of the second supporting plate is fixedly connected with a fourth rotating shaft, the position of the bottom end of the interior of the second sleeve, which is close to the central line, is fixedly connected with a hydraulic telescopic rod, the top end of the hydraulic telescopic rod is connected with a supporting rod, the two sides of the, and the bottom end of the diamond-shaped expansion bracket is fixedly connected with the fourth rotating shaft.

As a further description of the above technical solution:

First backup pad passes through to constitute sliding structure between fourth slider and the fourth spout, the rhombus expansion bracket passes through to constitute rotating-structure between fifth axis of rotation and the bracing piece, and the bracing piece passes through to constitute elevation structure between hydraulic telescoping rod and the second sleeve, first backup pad passes through to constitute elevation structure between third axis of rotation and the rhombus expansion bracket.

In conclusion, owing to adopted above-mentioned technical scheme, the utility model discloses following beneficial effect has:

1. The utility model discloses in, through drawing to rise or shrink first movable cross beam and second movable cross beam, the position of steerable shock wave probe makes things convenient for patient to lie and goes into testing platform, can adjust the angle of shock wave probe through rotating first axis of rotation, ensures the needs that the treatment instrument angle need be adjusted to the treatment in-process.

2. The utility model discloses in, through the pulling handle, can stimulate the second slide, just can control the total length between first slide and the second slide and satisfy different height patient's demand and the gyro wheel that the second slide passes through the axis of rotation of inner wall both sides and connects, reduced the friction between first slide and the second slide, can prolong the life of spare part.

3. The utility model discloses in, can drive the flexible of rhombus expansion bracket through hydraulic telescoping rod to realize the rising of base or reduce, with detection platform about satisfying special personnel such as the disabled, also can make things convenient for the demand of different height doctors to the operating instrument height.

Drawings

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

FIG. 2 is a front view of the structure of the present invention;

FIG. 3 is a cross-sectional view of the treatment device of the present invention;

FIG. 4 is a schematic cross-sectional view of a first parallel beam structure of the therapeutic device of the present invention;

FIG. 5 is a schematic cross-sectional view of a second parallel beam structure of the therapeutic device of the present invention;

FIG. 6 is a schematic structural view of a detection platform mechanism of the present invention;

FIG. 7 is a schematic view of a part of the structure of the detection platform mechanism of the present invention;

Fig. 8 is a schematic structural view of the lifting mechanism of the present invention;

Fig. 9 is a side view of the structure of the middle lifting mechanism of the present invention.

Illustration of the drawings:

1. A support table; 2. a treatment mechanism; 3. a detection platform; 4. a lifting base; 201. a first rotating shaft; 202. a straight bracket; 203. a first parallel beam; 204. a first chute; 205. a first movable beam; 206. a first shock wave probe; 207. a first slider; 208. a second parallel beam; 209. a second chute; 2010. a second movable beam; 2011. a second shock wave probe; 2012. a second slider; 301. A first slide plate; 302. a third chute; 303. a roller; 304. a second slide plate; 305. a second rotating shaft; 306. pulling a handle; 401. a first sleeve; 402. a fourth chute; 403. a fourth slider; 404. a first support plate; 405. a third rotating shaft; 406. a second sleeve; 407. a second support plate; 408. a fourth rotating shaft; 409. a diamond-shaped expansion bracket; 4010. a hydraulic telescopic rod; 4011. a support bar; 4012. a fifth rotating shaft.

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 of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-9, a micro-energy shock wave therapeutic apparatus fixing support comprises a support table 1, a therapeutic mechanism 2 is installed on one side of the support table 1, a first rotating shaft 201 is included inside the therapeutic mechanism 2, a straight support 202 is connected to one side of the first rotating shaft 201, the other side of the first rotating shaft 201 is fixedly connected to the support table 1, a first parallel beam 203 is fixedly connected to the top end of the straight support 202, a first chute 204 is respectively connected to two sides of the first parallel beam 203 in an embedded manner, a first moving beam 205 is connected to the outside of the first parallel beam 203 in a sleeved manner, a first shock wave probe 206 is fixedly connected to the bottom end of the first moving beam 205, a first slider 207 is respectively connected to two sides of the inner wall of the first moving beam 205, the first slider 207 is connected to the first chute 204 in a sleeved manner, a second parallel beam 208 is fixedly connected to the bottom end of the straight support 202, and the both sides of second parallel beam 208 are connected with second spout 209 respectively, the outside of second parallel beam 208 cup joints and is connected with second movable beam 2010, and the top fixedly connected with second shock wave probe 2011 of second movable beam 2010, the inner wall both sides of second movable beam 2010 are connected with second slider 2012 respectively, and for cup jointing between second slider 2012 and the second spout 209, testing platform 3 is installed to the top of second shock wave probe 2011, and lifting pedestal 4 is installed to testing platform 3's bottom.

Further, the straight bracket 202 forms a rotating structure with the support table 1 through the first rotating shaft 201, the first movable beam 205 forms a sliding structure with the first chute 204 through the first slider 207, the second movable beam 2010 forms a sliding structure with the second chute 209 through the second slider 2012, the first movable beam 205 can freely extend and retract with the second movable beam 2010 through the sliding structure formed between the second slider 2012 and the second chute 209 and the sliding structure formed between the first slider 207 and the first chute 204 and the second movable beam 2010, so that the first shock wave probe 206 and the second shock wave probe 2011 can be retracted when not in use.

Further, testing platform 3 is inside including first slide 301, and the both sides of first slide 301 gomphosis respectively are connected with third spout 302, the internal connection of third spout 302 has gyro wheel 303, and one side fixedly connected with second axis of rotation 305 of gyro wheel 303, first slide 301's outside cup joints and is connected with second slide 304, and the inner wall both sides of second slide 304 respectively with second axis of rotation 305 between be fixed connection, one side fixedly connected with of first slide 301 draws handle 306 and draws handle 306 can conveniently stretch or shrink second slide 304.

Furthermore, the third sliding chute 302 is connected with the roller 303 in a sleeved manner, the third sliding chute 302 forms a rolling structure with the second rotating shaft 305 through the roller 303, and the roller 303 slides in the third sliding chute 302 to reduce the friction between the second sliding plate 304 and the first sliding plate 301.

Further, a first sleeve 401 is included in the lifting base 4, the positions of the top end of the interior of the first sleeve 401, which are close to the two sides of the inner wall, are respectively connected with a fourth sliding chute 402 in a jogged manner, the interior of the fourth sliding chute 402 is respectively connected with a fourth sliding block 403 in a sleeved manner, the bottom end of the fourth sliding block 403 is respectively connected with a first supporting plate 404, one side of the first supporting plate 404 is connected with a third rotating shaft 405, the exterior of the first sleeve 401 is connected with a second sleeve 406 in a sleeved manner, the positions of the bottom end of the second sleeve 406, which are close to the two sides of the inner wall, are respectively and fixedly connected with a second supporting plate 407, one side of the second supporting plate 407 is fixedly connected with a fourth rotating shaft 408, the position of the bottom end of the interior of the second sleeve 406, which is close to the center line, is fixedly connected with a hydraulic telescopic rod 4010, the top end of the hydraulic telescopic, the top end of the rhombic expansion bracket 409 is fixedly connected with the third rotating shaft 405, the bottom end of the rhombic expansion bracket 409 is fixedly connected with the fourth rotating shaft 408, and the pressure intensity at the contact point of the first sleeve 401 can be reduced compared with that at the contact point of the hydraulic telescopic rod 4010 by the aid of the rhombic expansion bracket 409.

Further, first backup pad 404 passes through and constitutes sliding structure between fourth slider 403 and the fourth spout 402, rhombus expansion bracket 409 constitutes rotating structure between through fifth axis of rotation 4012 and bracing piece 4011, and bracing piece 4011 passes through and constitutes elevation structure between hydraulic telescoping rod 4010 and the second sleeve 406, first backup pad 404 passes through and constitutes elevation structure between third axis of rotation 405 and the rhombus expansion bracket 409, be fixed connection between first backup pad 404 and the third axis of rotation 405, it can normally stretch out and draw back to have ensured rhombus expansion bracket 409, and constitute elevation structure between first backup pad 404 through third axis of rotation 405 and the rhombus expansion bracket 409.

The working principle is as follows: when the device is used, the support rod 4011 is driven to move up and down through the hydraulic telescopic rod 4010, so that the support rod 4011 provides an upward pushing force for the rhombic expansion bracket 409 through the fifth rotating shafts 4012 at the two ends, the fourth rotating shaft 408 and the second support plate 407 provide a pulling force for the rhombic expansion bracket 409, the pushing force and the pulling force lead the rhombic expansion bracket 409 to deform so as to push the third rotating shaft 405 upwards or pull the rhombic expansion bracket 409 downwards, the third rotating shaft 405 conducts the deformation from the rhombic expansion bracket 409 to the first sleeve 401 through the first support plate 404, so that the first sleeve 401 moves up and down, the detection platform 3 at the top end of the first sleeve 401 is driven to move up and down, the patient can move up and down conveniently finally, the pull handle 306 at one side of the second sliding plate 304 is pulled, the second rotating shafts 305 connected with the two sides of the inner wall of the second sliding plate 304 are driven, and the rollers 303 connected with, the total length between the second sliding plate 304 and the first sliding plate 301 is controlled, so that the length is adjusted to meet the requirements of patients with different heights, the first moving beam 205 or the second moving beam 2010 is pulled, the first slider 207 and the second slider 2012 connected to two sides of the inner wall of the first moving beam 205 or the second moving beam 2010 can slide in the first sliding groove 204 and the second sliding groove 209, so that the first moving beam 205 and the second moving beam 2010 can be respectively pushed or pulled out on the surfaces of the first parallel beam 203 and the second parallel beam 208, the first rotating shaft 201 is rotated to drive the straight bracket 202 to rotate, the straight bracket 202 drives the first parallel beam 203, the first moving beam 205, the second parallel beam 208 and the second moving beam 2010 connected to rotate, and therefore the first shock wave probe 206 and the second shock wave probe 2011 at the bottom ends of the first moving beam 205 and the second moving beam 2010 are treated to have angular deviation, realizing the special requirements for the treatment part of the body of the patient.

The above is only the specific implementation manner of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the design of the present invention, equivalent replacement or change should be covered within the protection scope of the present invention.

Claims (6)

1. The utility model provides a micro energy shock wave treatment instrument fixed bolster, includes brace table (1), its characterized in that: the treatment mechanism (2) is installed on one side of the support table (1), the first rotating shaft (201) is arranged inside the treatment mechanism (2), one side of the first rotating shaft (201) is connected with a straight support (202), the other side of the first rotating shaft (201) is fixedly connected with the support table (1), the top end of the straight support (202) is fixedly connected with a first parallel cross beam (203), the two sides of the first parallel cross beam (203) are respectively connected with a first sliding chute (204) in an embedded mode, the outer portion of the first parallel cross beam (203) is connected with a first movable cross beam (205) in a sleeved mode, the bottom end of the first movable cross beam (205) is fixedly connected with a first shock wave probe (206), the two sides of the inner wall of the first movable cross beam (205) are respectively connected with first sliding blocks (207), and the first sliding blocks (207) are connected with the first sliding chutes (204) in a sleeved mode, bottom fixedly connected with second parallel beam (208) of straight type support (202), and the both sides of second parallel beam (208) are connected with second spout (209) respectively, the outside of second parallel beam (208) is cup jointed and is connected with second movable beam (2010), and the top fixedly connected with second shock wave probe (2011) of second movable beam (2010), the inner wall both sides of second movable beam (2010) are connected with second slider (2012) respectively, and are cup jointed for being connected between second slider (2012) and second spout (209), testing platform (3) are installed to the top of second shock wave probe (2011), and lifting base (4) are installed to the bottom of testing platform (3).

2. The micro-energy shock wave therapy instrument fixing support according to claim 1, wherein the straight support (202) forms a rotating structure with the support table (1) through a first rotating shaft (201), the first movable beam (205) forms a sliding structure with the first sliding chute (204) through a first sliding block (207), and the second movable beam (2010) forms a sliding structure with the second sliding chute (209) through a second sliding block (2012).

3. The micro-energy shock wave treatment instrument fixing support according to claim 1, wherein a first sliding plate (301) is arranged inside the detection platform (3), third sliding grooves (302) are respectively embedded and connected to two sides of the first sliding plate (301), rollers (303) are connected to the inside of the third sliding grooves (302), a second rotating shaft (305) is fixedly connected to one side of each roller (303), a second sliding plate (304) is connected to the outside of the first sliding plate (301) in a sleeved mode, two sides of the inner wall of the second sliding plate (304) are fixedly connected to the second rotating shaft (305), and a pull handle (306) is fixedly connected to one side of the first sliding plate (301).

4. The micro-energy shock wave therapy apparatus fixing support according to claim 3, wherein the third sliding groove (302) is connected with the roller (303) in a sleeved manner, and the third sliding groove (302) forms a rolling structure with the second rotating shaft (305) through the roller (303).

5. The micro-energy shock wave therapeutic apparatus fixing support according to claim 1, wherein the lifting base (4) comprises a first sleeve (401), the top end of the first sleeve (401) is connected with a fourth sliding chute (402) near to the two sides of the inner wall in a embedding manner, the fourth sliding chute (402) is connected with a fourth sliding block (403) in a sleeving manner, the bottom end of the fourth sliding block (403) is connected with a first supporting plate (404) in a sleeving manner, one side of the first supporting plate (404) is connected with a third rotating shaft (405), the first sleeve (401) is connected with a second sleeve (406) in a sleeving manner, the bottom end of the second sleeve (406) is connected with a second supporting plate (407) near to the two sides of the inner wall in a fixedly manner, one side of the second supporting plate (407) is connected with a fourth rotating shaft (408), the bottom end of the second sleeve (406) is connected with a hydraulic telescopic rod (4010) near to the center line, and the top of hydraulic telescoping rod (4010) is connected with bracing piece (4011), the both sides difference fixedly connected with fifth axis of rotation (4012) of bracing piece (4011), and one side of fifth axis of rotation (4012) is connected with rhombus expansion bracket (409), be fixed connection between the top of rhombus expansion bracket (409) and third axis of rotation (405), and be fixed connection between the bottom of rhombus expansion bracket (409) and fourth axis of rotation (408).

6. The micro-energy shock wave therapeutic apparatus fixing support according to claim 5, wherein the first support plate (404) forms a sliding structure through a fourth sliding block (403) and a fourth sliding groove (402), the diamond-shaped expansion bracket (409) forms a rotating structure through a fifth rotating shaft (4012) and a support rod (4011), the support rod (4011) forms a lifting structure through a hydraulic telescopic rod (4010) and a second sleeve (406), and the first support plate (404) forms a lifting structure through a third rotating shaft (405) and the diamond-shaped expansion bracket (409).

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