CN113686857A

CN113686857A - Glass sheet box rotary lifting structure for bone marrow smear scanner

Info

Publication number: CN113686857A
Application number: CN202111013326.4A
Authority: CN
Inventors: 赵宝成; 楼益佳; 刘昭秀; 陆涛; 陆炬; ***
Original assignee: Hangzhou Zhiwei Information Technology Co ltd
Current assignee: Hangzhou Zhiwei Information Technology Co ltd
Priority date: 2021-08-31
Filing date: 2021-08-31
Publication date: 2021-11-23
Anticipated expiration: 2041-08-31
Also published as: CN113686857B

Abstract

The invention discloses a glass slide box rotary lifting structure for a bone marrow smear scanner, which comprises a front panel, a top plate, a left panel, a right panel, a bottom plate and a rear panel, wherein the front panel is provided with a receiving installation seat, a laser receiving circuit board is installed on the receiving installation seat, and a glass slide inlet and a glass slide outlet are arranged below the receiving installation seat; the rear panel is provided with an emission mounting seat, a first laser rotation adjusting seat and a second laser rotation adjusting seat are symmetrically arranged on the emission mounting seat, a first emission head is arranged on the first laser rotation adjusting seat, and a second emission head is arranged on the second laser rotation adjusting seat; the lifting mechanism comprises a left panel, a first mounting support and a second mounting support, wherein the first mounting support and the second mounting support are respectively mounted on the upper side and the lower side of the left panel, and the rotating mechanism comprises a rotating shaft and a rotating assembly mounted on the rotating shaft.

Description

Glass sheet box rotary lifting structure for bone marrow smear scanner

Technical Field

The invention belongs to the field of medical equipment, and particularly relates to a slide box rotary lifting structure for a bone marrow smear scanner.

Background

Most of the existing bone marrow cell image collection are carried out by placing glass slides on an objective table respectively, focusing and image collection are carried out on the glass slides by moving the objective table, and in the process, an operator needs to manually place the glass slides on the objective table one by one and take the glass slides out of the objective table.

Disclosure of Invention

The present invention is directed to overcome the above-mentioned deficiencies in the prior art and to provide a slide cassette rotary elevating structure for a bone marrow smear scanner.

The technical scheme adopted by the invention for solving the problems is as follows:

the rotary glass slide box lifting structure for the bone marrow smear scanner comprises a front panel, a top plate, a left panel, a right panel, a bottom plate and a rear panel, wherein a receiving mounting seat is arranged on the front panel, a laser receiving circuit board is mounted on the receiving mounting seat, and a glass slide inlet and a glass slide outlet are arranged below the receiving mounting seat; the rear panel is provided with an emission mounting seat, a first laser rotation adjusting seat and a second laser rotation adjusting seat are symmetrically arranged on the emission mounting seat, a first emission head is arranged on the first laser rotation adjusting seat, and a second emission head is arranged on the second laser rotation adjusting seat; a lifting mechanism and a rotating mechanism are arranged in an inner space formed by the front panel, the rear panel, the left panel and the right panel, the lifting mechanism comprises a left panel, and a first mounting bracket and a second mounting bracket which are respectively mounted above and below the left panel, a first supporting unit is arranged on the first mounting bracket, a second supporting unit is arranged on the second mounting bracket, a ball screw is erected between the first supporting unit and the second supporting unit, a ball nut is configured on the ball screw, a connecting seat is fixed on the ball nut, and the connecting seat is fixedly connected with the rotating mechanism; the rotating mechanism comprises a rotating shaft and a rotating assembly arranged on the rotating shaft, wherein the rotating assembly comprises two bearing seats, a bearing, a front half bin fixedly connected with the bearing seats and a rear half bin fixedly arranged through the rotating shaft.

Preferably, the lifting mechanism further comprises a first motor support arranged above the left panel, a first photoelectric switch and a second photoelectric switch which are symmetrically arranged on the left panel, and a first linear guide rail arranged between the first mounting support and the second mounting support, the first motor support is provided with a first stepping motor, the first linear guide rail is provided with a sliding block, and the sliding block is fixedly connected with the connecting seat.

Preferably, the slider is provided with a first sensing piece which is sensed by the first photoelectric switch and a second sensing piece which is sensed by the second photoelectric switch.

Preferably, a coupling is arranged between the first stepping motor and the ball screw, and the coupling is used for controlling the rotation of the ball screw by the first stepping motor.

Preferably, the rotating mechanism further comprises a second motor support fixed on the right side of the front half bin, a second linear guide rail and a gear fixed at the right end of the rotating shaft, a second stepping motor is mounted on the second motor support, the second stepping motor is provided with a rotating shaft, a supporting seat is arranged below the rotating shaft, a connecting slide block is further arranged on the rotating shaft, the other side of the connecting slide block is arranged on the second linear guide rail, the connecting slide block can slide along the second linear guide rail under the driving of the second stepping motor, and a rack meshed with the gear is further fixed on the connecting slide block; and limiting blocks are arranged at two ends of the second linear guide rail.

Preferably, the top of the front half bin is provided with a stop block for limiting the rotation of the rear half bin; and the right side of the front half bin is also provided with an induction sheet for inducing the rotation of the rear half bin to a specified position.

Preferably, a travel switch support is arranged on the right side of the rear half bin, a first travel switch and a second travel switch are symmetrically arranged on the travel switch support, a photoelectric switch support is further arranged below the travel switch support in the rear half bin, and a photoelectric switch is arranged on the photoelectric switch support.

Preferably, the rear panel is further provided with a first rotary limiting plate and a second rotary limiting plate side by side, the first rotary limiting plate is provided with a first rotary induction sheet, and the second rotary limiting plate is provided with a second rotary induction sheet.

Preferably, a first guide bolt and a second guide bolt are arranged on the left panel, a third guide bolt and a fourth guide bolt are arranged on the right panel, 4 screw holes corresponding to the first guide bolt, the second guide bolt, the third guide bolt and the fourth guide bolt are formed in the front panel, and a first guide nut, a second guide nut, a third guide nut and a fourth guide nut which penetrate through the screw holes are respectively matched with the first guide bolt, the second guide bolt, the third guide bolt and the fourth guide bolt one by one.

Preferably, the first guide nut, the second guide nut, the third guide nut and the fourth guide nut are provided with compression springs at the joints corresponding to the screw holes, and the compression springs are used for damping the front panel.

Compared with the prior art, the invention has the following advantages and effects: the invention can realize the lifting and the rotation of the slide box when the image of the bone marrow smear is collected, so that the slide box loaded with the bone marrow smear can be accurately moved to the appointed shooting area, and the shot slide box is transported out for the next round of shooting; simple structure, easy operation can satisfy the continuous speech operation of marrow smear, improves work efficiency.

Drawings

FIG. 1 is a schematic perspective view of a slide cassette rotary elevating structure for a bone marrow smear scanner according to the present invention;

FIG. 2 is a schematic front view of the structure of FIG. 1;

FIG. 3 is a schematic left side view of the structure of FIG. 1;

FIG. 4 is a schematic top view of the structure of FIG. 1;

FIG. 5 is a front view schematic of the internal lift mechanism and rotation mechanism of FIG. 1;

FIG. 6 is a schematic perspective view of the lift mechanism of FIG. 5;

FIG. 7 is a schematic diagram of the right side view of the structure of FIG. 6;

FIG. 8 is a schematic perspective view of the rotary mechanism of FIG. 5;

FIG. 9 is a schematic diagram of the right-hand side view of the rotary mechanism of FIG. 8;

FIG. 10 is a schematic top view of the structure of FIG. 8;

fig. 11 is a schematic sectional view in the direction of a-a in fig. 10.

Description of reference numerals: 1. a front panel; 2. a top plate; 3. a left panel; 4. a right panel; 5. a base plate; 6. a rear panel; 7. a lifting mechanism; 8. a rotation mechanism; 9. a cassette for glass sheets; 11. receiving the mounting seat; 12. a laser receiving circuit board; 13. a slide inlet and outlet; 31. a first guide nut; 32. a first guide bolt; 33. a compression spring; 34. a second guide nut; 35. a second guide bolt; 41. a third guide nut; 42. a third guide bolt; 43. a fourth guide nut; 44. a fourth guide bolt; 61. a launch mount; 62. a first laser rotation adjusting seat; 63. a first transmitting head; 64. a second laser rotation adjusting seat; 65. a second emitter head; 66. a first rotary limit plate; 67. a first rotation sensing piece; 68. a second rotating limit plate; 69. a second rotation sensing piece; 71. a first stepper motor; 72. a first motor bracket; 73. a coupling; 74. a first mounting bracket; 75. a first supporting unit; 76. a first linear guide rail; 77. a ball screw; 78. a connecting seat; 79. a second mounting bracket; 710. a second supporting unit; 711. a first photoelectric switch; 712. a first sensing piece; 713. a second sensing piece; 714. a second photoelectric switch; 715. a ball nut; 716. a slider; 81. a first half bin; 82. the second half of the bin; 83. a second motor support; 84. a second stepping motor; 85. a supporting seat; 86. connecting the sliding block; 87. a rack; 88. a gear; 89. a second linear guide; 810. a limiting block; 811. an induction sheet; 812. a travel switch bracket; 813. a first travel switch; 814. a second travel switch; 815. a photoelectric switch; 816. a photoelectric switch bracket; 817. rotating shaft, 818, bearing; 819. a bearing seat; 820. a stopper; 821. a rotating shaft.

Detailed Description

The present invention will be described in further detail below by way of examples with reference to the accompanying drawings, which are illustrative of the present invention and are not to be construed as limiting the present invention.

Examples are given.

Referring to fig. 1 to 4, the slide cassette rotary lifting structure for a bone marrow smear scanner of the present invention comprises a front panel 1, a top plate 2, a left panel 3, a right panel 4, a bottom plate 5 and a rear panel 6, wherein the front panel 1 is provided with a receiving mounting seat 11, the receiving mounting seat 11 is provided with a laser receiving circuit board 12, and the laser receiving circuit board 12 is used for receiving laser signals and converting the laser signals into electrical signals; a slide inlet and outlet 13 is arranged below the receiving mounting seat 11, when the bone marrow smear is scanned, the slide is drawn out of the slide box 9 from the slide inlet and outlet 13, and after the shooting is finished, the slide is put into the slide box 9 from the slide inlet and outlet 13; a first guide bolt 32 and a second guide bolt 35 are arranged on the left panel 3, a third guide bolt 42 and a fourth guide bolt 44 are arranged on the right panel 4, 4 screw holes corresponding to the first guide bolt 32, the second guide bolt 35, the third guide bolt 42 and the fourth guide bolt 44 are respectively arranged on the front panel 1, a first guide nut 31 and a second guide nut 34 are fixed on the left panel 3 and are respectively matched with the first guide bolt 32 and the second guide bolt 35 one by one, a third guide nut 41 and a fourth guide nut 43 are fixed on the right panel 4 and are respectively matched with the third guide bolt 42 and the fourth guide bolt 44 one by one, and the first guide bolt 31, the second guide nut 34, the third guide nut 41 and the fourth guide nut 43 which pass through the first guide nut 31, the second guide nut 34, the third guide nut 41 and the fourth guide nut 43 and are respectively connected with the corresponding screw holes, The fourth guide bolts 44 are each provided with a compression spring 33 for damping the shock of the front panel 1.

The rear panel 6 is provided with an emission mounting seat 61, the emission mounting seat 61 is symmetrically provided with a first laser rotation adjusting seat 62 and a second laser rotation adjusting seat 64, the first laser rotation adjusting seat 61 is provided with a first emission head 63, the second laser rotation adjusting seat 64 is provided with a second emission head 65, and the first emission head 63 and the second emission head 65 are both used for laser emission; the rear panel 6 is further provided with a first rotary limiting plate 66 and a second rotary limiting plate 68 side by side, the first rotary limiting plate 66 is provided with a first rotary sensing piece 67, the second rotary limiting plate 68 is provided with a second rotary sensing piece 69, and the first rotary sensing piece 67 and the second rotary sensing piece 69 are used for sensing rotation to a position.

Each panel of the embodiment of the invention adopts 6061-T6 aluminum alloy, and has good hardness and corrosion resistance.

Referring to fig. 5 to 11, in the embodiment of the present invention, an elevating mechanism 7 and a rotating mechanism 8 are disposed in an inner space formed by the front panel 1, the rear panel 6, the left panel 3 and the right panel 4, the elevating mechanism 7 includes the left panel 3, and a first mounting bracket 74 and a second mounting bracket 79 respectively mounted on the upper and lower sides of the left panel 3, a first supporting unit 75 is disposed on the first mounting bracket 74, a second supporting unit 710 is disposed on the second mounting bracket 79, a ball screw 77 is disposed between the first supporting unit 75 and the second supporting unit 710, a ball nut 715 is disposed on the ball screw 77, a connecting seat 78 is fixed on the ball nut 715, and the right side of the connecting seat 78 is fixedly connected with the rotating mechanism 8; a first linear guide rail 76 is further arranged between the first mounting bracket 74 and the second mounting bracket 79, a sliding block 716 is arranged on the first linear guide rail 76, and the sliding block 716 is fixedly connected with the left side of the connecting seat 78.

In addition, the lifting mechanism 7 of the embodiment of the present invention further includes a first motor bracket 72 installed above the left panel 3, and a first photoelectric switch 711 and a second photoelectric switch 714 symmetrically installed on the left panel 3, wherein a first stepping motor 71 is installed on the first motor bracket 72, the first stepping motor 71 is connected to a coupler 73, the other side of the coupler 73 is fixedly connected to the ball screw 77, and the first stepping motor 71 drives the ball screw 77 to rotate through the coupler 73.

The slider 716 is further provided with a first sensing piece 712 and a second sensing piece 713 in parallel, the first sensing piece 712 receives a laser signal to control the first photoelectric switch 711 to operate, and the second sensing piece 713 receives a laser signal to control the second photoelectric switch 714 to operate.

The rotating mechanism 8 of the embodiment of the present invention includes a rotating shaft 817 and a rotating assembly installed on the rotating shaft 817, where the rotating assembly includes two symmetrically arranged bearing seats 819, a bearing 818, a front half-bin 81 fixedly connected with the bearing seats 819, and a rear half-bin 82 fixedly arranged through the rotating shaft 817. The rotating mechanism 8 further comprises a second motor support 83 fixed on the right side of the front half bin 81, a second linear guide rail 89 and a gear 88 fixed at the right end of the rotating shaft 817, a second stepping motor 84 is mounted on the second motor support 83, the second stepping motor 84 is connected with a rotating shaft 821, a support seat 85 is arranged below the rotating shaft 821, a connecting slide block 86 is further arranged on the rotating shaft 821, a through hole is formed in one side of the connecting slide block 86, a thread matched with the thread of the rotating shaft 821 is arranged in the through hole, the rotating shaft 821 penetrates through the through hole, the other side of the connecting slide block 86 is arranged on the second linear guide rail 89, and the connecting slide block 86 can slide up and down along the second linear guide rail 89 under the condition that the second stepping motor 84 works to drive the rotating shaft 821 to rotate; both ends of the second linear guide 89 are provided with limit blocks 810 for limiting the moving displacement of the connecting slide block 86. The connecting slide block 86 is further fixed with a rack 87 engaged with the gear 88, the connecting slide block 86 moves upwards to drive the gear 88 to rotate clockwise, so that the rear half bin 82 is driven to rotate clockwise by 90 degrees and is changed from a vertical state to a horizontal state, and a rotating function is realized. The top of the front half-bin 81 is provided with a stop 820 for limiting the rotation of the rear half-bin 82; the right side of the front half chamber 81 is also provided with a sensing piece 811 for sensing that the rear half chamber 82 rotates to a specified position.

In addition, a travel switch bracket 812 is arranged on the right side of the rear half bin 82, a first travel switch 813 and a second travel switch 814 are symmetrically arranged on the travel switch bracket 812, the first travel switch 813 and the second travel switch 814 are both used for controlling the up-and-down movement travel of the rotating mechanism 8, and the rotating mechanism 8 is controlled to stop moving when moving to a specified position; the rear half cabin 82 is also provided with a photoelectric switch bracket 816 below the travel switch bracket 812, and a photoelectric switch 815 is arranged on the photoelectric switch bracket 816.

The front half chamber 81 and the rear half chamber 82 of the embodiment of the present invention are each provided with an opening, which is slightly larger than the opening of the slide cassette 9, so that the slide can be taken out and put back during the photographing process.

When the embodiment of the invention works, the initial position of the rotating mechanism 8 is positioned at the top of the rotating and lifting structure of the glass box, the rear half chamber 82 of the rotating mechanism 8 is positioned at the horizontal position, the glass box 9 is transversely transported to the rear half chamber 82 of the rotating mechanism 8, then the second stepping motor 84 starts to work to drive the rack 87 to move downwards, so as to drive the gear 88 to rotate anticlockwise and also drive the rear half chamber 82 to rotate anticlockwise, the horizontal direction is changed into the vertical direction, and at the moment, the glass box 9 is erected in a space formed by the front half chamber 81 and the rear half chamber 82 of the rotating mechanism 8; then the first step motor 71 of the lifting mechanism 7 works to drive the ball screw 77 to rotate, thereby driving the rotating mechanism 8 to move downwards to a designated position for taking a bone marrow smear image, the mechanical arm penetrates through the slide inlet and outlet 13 to extract a slide from the slide box 9 for taking, after the taking is finished, the mechanical arm puts the slide back to the slide box 9, after all slides are taken, the first step motor 71 of the lifting mechanism 7 continues to work, the rotating mechanism 8 moves downwards to the lower part to stop working, at the moment, the second step motor 84 starts to work, drives the rack 87 to move upwards, thereby driving the gear 88 to rotate clockwise, also driving the rear half chamber 82 to rotate clockwise, changing the vertical direction into the horizontal direction, and then the slide box 9 is transported out transversely. After the slide box 9 is transported out, the rear half chamber 82 of the rotating mechanism 8 is changed from horizontal rotation to vertical direction, and the lifting mechanism 7 drives the rotating mechanism 8 to ascend to the top to continue the next round of shooting.

The rotating and lifting structure of the slide box as a bone marrow smear scanner is simple in structure, is important as a loop of an automatic bone marrow smear digital acquisition process, realizes the rotation and the accurate movement of the slide box 9, enables the shooting process to be more time-saving and labor-saving, is stable in operation, and is more convenient to transport due to the arrangement of the compression spring 33 between panels.

In addition, it should be noted that the specific embodiments described in the present specification may be different in the components, the shapes of the components, the names of the components, and the like, and the above description is only an illustration of the structure of the present invention. Equivalent or simple changes in the structure, characteristics and principles of the invention are included in the protection scope of the patent. Various modifications, additions and substitutions for the specific embodiments described may be made by those skilled in the art without departing from the scope of the invention as defined in the accompanying claims.

Claims

1. A glass slide box rotary lifting structure for a bone marrow smear scanner comprises a front panel, a top plate, a left panel, a right panel, a bottom plate and a rear panel, and is characterized in that the front panel is provided with a receiving installation seat, a laser receiving circuit board is installed on the receiving installation seat, and a glass slide inlet and a glass slide outlet are arranged below the receiving installation seat; the rear panel is provided with an emission mounting seat, a first laser rotation adjusting seat and a second laser rotation adjusting seat are symmetrically arranged on the emission mounting seat, a first emission head is arranged on the first laser rotation adjusting seat, and a second emission head is arranged on the second laser rotation adjusting seat; a lifting mechanism and a rotating mechanism are arranged in an inner space formed by the front panel, the rear panel, the left panel and the right panel, the lifting mechanism comprises a left panel, and a first mounting bracket and a second mounting bracket which are respectively mounted above and below the left panel, a first supporting unit is arranged on the first mounting bracket, a second supporting unit is arranged on the second mounting bracket, a ball screw is erected between the first supporting unit and the second supporting unit, a ball nut is configured on the ball screw, a connecting seat is fixed on the ball nut, and the connecting seat is fixedly connected with the rotating mechanism; the rotating mechanism comprises a rotating shaft and a rotating assembly arranged on the rotating shaft, wherein the rotating assembly comprises two bearing seats, a bearing, a front half bin fixedly connected with the bearing seats and a rear half bin fixedly arranged through the rotating shaft.

2. The rotary elevating structure of a slide cassette for a bone marrow smear scanner according to claim 1, wherein the elevating mechanism further comprises a first motor bracket installed above the left panel, a first photoelectric switch and a second photoelectric switch symmetrically installed on the left panel, and a first linear guide rail installed between the first installation bracket and the second installation bracket, the first motor bracket is installed with a first stepping motor, the first linear guide rail is provided with a slide block, and the slide block is fixedly connected with the connecting seat.

3. The rotary elevating structure of a slide cassette for a bone marrow smear scanner according to claim 2, wherein the slide block is respectively provided with a first sensing piece sensing the first photoelectric switch and a second sensing piece sensing the second photoelectric switch.

4. The structure of claim 1 or 2, wherein a coupling is arranged between the first stepping motor and the ball screw, and the first stepping motor controls the ball screw to rotate.

5. The rotary lifting structure of a slide box for a bone marrow smear scanner according to claim 1, wherein the rotary mechanism further comprises a second motor bracket fixed on the right side of the front half warehouse, a second linear guide rail and a gear fixed at the right end of the rotary shaft, a second stepping motor is mounted on the second motor bracket, the second stepping motor is provided with a rotary shaft, a support seat is arranged below the rotary shaft, a connecting slide block is further arranged on the rotary shaft, the other side of the connecting slide block is arranged on the second linear guide rail, the connecting slide block can slide along the second linear guide rail under the driving of the second stepping motor, and a rack engaged with the gear is further fixed on the connecting slide block; and limiting blocks are arranged at two ends of the second linear guide rail.

6. The rotary lifting structure of a slide box for a bone marrow smear scanner according to claim 1, wherein a stopper is provided at the top of the front half chamber for limiting the rotation of the rear half chamber; and the right side of the front half bin is also provided with an induction sheet for inducing the rotation of the rear half bin to a specified position.

7. The rotary lifting structure of a slide cassette for a bone marrow smear scanner according to claim 1, wherein a travel switch bracket is provided on the right side of the rear half-chamber, a first travel switch and a second travel switch are symmetrically provided on the travel switch bracket, a photoelectric switch bracket is further provided below the travel switch bracket on the rear half-chamber, and a photoelectric switch is mounted on the photoelectric switch bracket.

8. The rotary lifting structure of a slide cassette for a bone marrow smear scanner according to claim 1, wherein the rear panel is further provided with a first rotary limiting plate and a second rotary limiting plate side by side, the first rotary limiting plate is provided with a first rotary induction sheet, and the second rotary limiting plate is provided with a second rotary induction sheet.

9. The rotary elevating structure of a slide cassette for a bone marrow smear scanner according to claim 1, wherein the left panel is provided with a first guide bolt and a second guide bolt, the right panel is provided with a third guide bolt and a fourth guide bolt, the front panel is provided with 4 screw holes corresponding to the first guide bolt, the second guide bolt, the third guide bolt and the fourth guide bolt, respectively, and a first guide nut, a second guide nut, a third guide nut and a fourth guide nut are arranged through the screw holes to be matched with the first guide bolt, the second guide bolt, the third guide bolt and the fourth guide bolt one by one.

10. The rotary elevating structure of a slide cassette for a bone marrow smear scanner according to claim 9, wherein the first, second, third and fourth guide nuts are provided with compression springs at the joints of the corresponding screw holes for shock absorption of the front panel.