CN218271901U

CN218271901U - Skin cell metabolic rate quantitative determination device

Info

Publication number: CN218271901U
Application number: CN202221794782.7U
Authority: CN
Inventors: 李利; 唐洁; 熊丽丹
Original assignee: West China Hospital of Sichuan University
Current assignee: West China Hospital of Sichuan University
Priority date: 2022-07-12
Filing date: 2022-07-12
Publication date: 2023-01-10
Anticipated expiration: 2032-07-12

Abstract

The utility model discloses a skin cell metabolic speed quantitative determination device relates to cell metabolism field, and to the skin cell metabolic speed quantitative determination device who exists on the present market when using, because it needs to be placed in the darkroom to need the operator together to be in among the darkroom, it is comparatively fixed to the installation of culture dish simultaneously, be not convenient for carry out the problem adjusted to it, now proposes following scheme, and it includes check out test set, check out test set's bottom is run through and is provided with and places the case, the inside of placing the case is provided with the culture dish, just the filter lid has been cup jointed at the top of culture dish, the bottom of culture dish is provided with first adjustment mechanism, just the bottom of first adjustment mechanism is provided with second adjustment mechanism. The placing box arranged inside the skin cell metabolism speed quantitative detection device is convenient for manufacturing a darkroom environment, and is matched with the first adjusting mechanism and the second adjusting mechanism to adjust two groups of different directions of the culture dish.

Description

Skin cell metabolic rate quantitative determination device

Technical Field

The utility model relates to a cell metabolism field especially relates to a skin cell metabolic rate quantitative determination device.

Background

Human part when skin cell metabolism, at present when carrying out quantitative determination to skin cell metabolic rate, the detection device who is suitable for need place whole device inside suggesting usually, and this mode needs the operator also to get into in the darkroom to this mode is comparatively single in the fixed of culture dish, can't adjust it, consequently has certain drawback when using.

The quantitative detection device for the skin cell metabolism speed aims at solving the problems that when the quantitative detection device for the skin cell metabolism speed existing in the market is used, an operator needs to be placed in a darkroom, and the operator needs to be in the darkroom together, and meanwhile, the culture dish is fixed to be installed, so that the quantitative detection device for the skin cell metabolism speed is inconvenient to adjust.

SUMMERY OF THE UTILITY MODEL

The utility model provides a pair of skin cell metabolic speed quantitative determination device has solved the skin cell metabolic speed quantitative determination device who exists on the present market when using, because it need place in the darkroom to need the operator together be in among the darkroom, comparatively fixed to the installation of culture dish simultaneously, be not convenient for carry out the problem adjusted to it.

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

the utility model provides a skin cell metabolic speed quantitative determination device, includes check out test set, check out test set's bottom is run through to be provided with and is placed the case, the inside of placing the case is provided with the culture dish, just the filter lid has been cup jointed at the top of culture dish, the bottom of culture dish is provided with first adjustment mechanism, just first adjustment mechanism's bottom is provided with second adjustment mechanism.

Preferably, first adjustment mechanism includes rack, spout, spacing axle, back shaft, a servo motor, first threaded rod, first connecting plate and mounting panel, the rack is located the bottom of culture dish, just the rack cup joints with the culture dish.

Preferably, the sliding chutes are symmetrically formed in two sides of the placing frame, the limiting shafts are symmetrically arranged in the sliding chutes, the supporting shafts are symmetrically arranged on two sides of the placing frame and are n-shaped, the supporting shafts penetrate through the sliding chutes and extend to the inside of the second adjusting mechanism, the supporting shafts are sleeved with the limiting shafts, and the supporting shafts and the limiting shafts are vertically distributed.

Preferably, two sets of be provided with the mounting panel between the back shaft, just the top of mounting panel is provided with first servo motor, first servo motor's output is provided with first threaded rod, just the circumference outer wall threaded connection of first threaded rod has first connecting plate, the top of first connecting plate and the bottom fixed connection of rack.

Preferably, the second adjusting mechanism comprises a second servo motor, a second connecting plate, a second threaded rod, guide rails and supporting plates, the guide rails are arranged in two groups and are symmetrically distributed relative to the placing rack, and the guide rails are matched with the supporting shafts.

Preferably, two sets of be provided with the backup pad between the guide rail, just the top of backup pad is provided with second servo motor, just second servo motor's output is provided with the second threaded rod, the circumference outer wall threaded connection of second threaded rod has the second connecting plate, just the top and the mounting panel fixed connection of second connecting plate.

The utility model has the advantages that:

1. the inside case of placing that sets up of the device is convenient for form the darkroom space to the culture dish to avoided the operator to get into the darkroom and operated, and the light filter that the device is inside to set up is convenient for filter the light source that check out test set sent, thereby makes during suitable light source jetes into the culture dish, and then makes things convenient for the skin cell to observe in the culture dish more.

2. The inside first adjustment mechanism that sets up of the device cooperates second adjustment mechanism and is convenient for adjust two sets of directions of culture dish respectively, and then makes things convenient for more and observes the inside skin cell of culture dish, can avoid artifical entering darkroom round trip movement culture dish simultaneously.

In conclusion, the placing box arranged inside the device is convenient for manufacturing a darkroom environment, and is matched with the first adjusting mechanism and the second adjusting mechanism to adjust two groups of culture dishes in different directions, so that manual operation in the darkroom is avoided.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a structural sectional view of the present invention.

Fig. 3 is an exploded view of the connection structure of the culture dish of the present invention.

Fig. 4 is a schematic structural diagram of the second adjusting mechanism of the present invention.

Fig. 5 is a sectional view of the connection structure of the first adjustment mechanism of the present invention.

Reference numbers in the figures: 1. placing a box; 2. a detection device; 3. a culture dish; 4. a filter cover; 5. a first adjustment mechanism; 501. placing a rack; 502. a chute; 503. a limiting shaft; 504. a support shaft; 505. a first servo motor; 506. a first threaded rod; 507. a first connecting plate; 508. mounting a plate; 6. a second adjustment mechanism; 601. a second servo motor; 602. a second connecting plate; 603. a second threaded rod; 604. a guide rail; 605. and a support plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the 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.

Referring to fig. 1-5, a quantitative skin cell metabolism velocity detection apparatus is provided, in which a placement box 1 is disposed at the bottom of a detection device 2 in a penetrating manner, a culture dish 3 is disposed inside the placement box 1, a filter cover 4 is sleeved on the top of the culture dish 3, a first adjustment mechanism 5 is disposed at the bottom of the culture dish 3, and a second adjustment mechanism 6 is disposed at the bottom of the first adjustment mechanism 5;

the placing box 1 is convenient for building a darkroom environment and avoids an operator from entering the darkroom for operation.

As shown in fig. 2, 3, and 5, the first adjusting mechanism 5 includes a placing rack 501, a chute 502, a limiting shaft 503, a supporting shaft 504, a first servo motor 505, a first threaded rod 506, a first connecting plate 507, and a mounting plate 508, the placing rack 501 is located at the bottom of the culture dish 3, the placing rack 501 is sleeved with the culture dish 3, the chute 502 is symmetrically formed on both sides of the placing rack 501, the limiting shaft 503 is symmetrically arranged inside the chute 502, the supporting shaft 504 is symmetrically arranged on both sides of the placing rack 501, the supporting shaft 504 is n-shaped, the supporting shaft 504 penetrates through the chute 502 and extends into the second adjusting mechanism 6, the supporting shaft 504 is sleeved with the limiting shaft 503, the supporting shaft 504 and the limiting shaft 503 are vertically distributed, the mounting plate 508 is arranged between the two sets of supporting shafts 504, the first servo motor 505 is arranged on the top of the mounting plate 508, the first threaded rod 506 is arranged on the output end of the first servo motor 505, the first threaded rod 506 is in threaded connection with the first connecting plate 507, and the top of the first connecting plate 507 is fixedly connected with the bottom of the placing rack 501;

the first servo motor 505 is matched with a first threaded rod 506 arranged at the output end of the first servo motor and is convenient for driving the placing rack 501 to move through a first connecting plate 507, and then the position of the culture dish 3 is changed.

As shown in fig. 2, 3, and 4, the second adjusting mechanism 6 includes a second servo motor 601, a second connecting plate 602, a second threaded rod 603, two sets of guide rails 604, and a support plate 605, wherein the two sets of guide rails 604 are symmetrically distributed about the placement frame 501, the guide rails 604 are matched with the support shaft 504, the support plate 605 is disposed between the two sets of guide rails 604, the second servo motor 601 is disposed on the top of the support plate 605, the second threaded rod 603 is disposed at an output end of the second servo motor 601, the second connecting plate 602 is in threaded connection with the outer circumferential wall of the second threaded rod 603, and the top of the second connecting plate 602 is fixedly connected with the mounting plate 508;

the second servo motor 601 is convenient to drive the first adjusting mechanism 5 to move through a second threaded rod 603 and a second connecting plate 602, which are arranged at the output end of the second servo motor, so as to drive the culture dish 3 to move.

When the utility model is used, the device is taken out firstly, and is placed at a proper position, and simultaneously, the device is connected with an external power supply;

at this time, the culture dish 3 with the skin cells is placed on the top of the placing frame 501 arranged in the placing box 1, the filtering cover 4 is taken out and placed on the top of the culture dish 3, and the skin cells in the culture dish 3 can be detected through the detection equipment 2 arranged on the top of the placing box 1 in a penetrating mode;

when the culture dish 3 needs to be adjusted, a first servo motor 505 arranged in the first adjusting mechanism 5 can be started, the first servo motor 505 rotates through a first threaded rod 506 arranged at the output end of the first servo motor to drive a first connecting plate 507 to move, and then the first connecting plate 507 drives the placing rack 501 to move, so that the culture dish 3 placed at the top of the placing rack 501 is driven to move, when the placing rack 501 moves, the sliding grooves 502 arranged at the two sides of the placing rack 501 are matched with the limiting shafts 503 to slide at the two sides of the supporting shaft 504, and the placing rack 501 is limited through the supporting shaft 504 until the placing rack 501 is adjusted to a proper position;

at this moment, the second servo motor 601 arranged inside the second adjusting mechanism 6 is started, the second servo motor 601 drives the second connecting plate 602 to move through the second threaded rod 603 arranged at the output end of the second servo motor, and the second connecting plate 602 is fixedly connected with the mounting plate 508 arranged inside the first adjusting mechanism 5, so that the second connecting plate 602 moves to drive the mounting plate 508 to move, further the supporting shafts 504 arranged on the outer side of the mounting plate 508 in an array mode are driven to move under the limiting of the two sets of guide rails 604, further the placing frame 501 arranged at the top of the mounting plate 508 is driven to move, and the position of the placing frame 501 is changed until the supporting shaft is moved to a proper position.

The above, only be the embodiment of the preferred 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 utility model, which are designed to be replaced or changed equally, all should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a skin cell metabolic rate quantitative determination device, includes check out test set (2), its characterized in that, the bottom of check out test set (2) is run through and is provided with places case (1), the inside of placing case (1) is provided with culture dish (3), just filter cover (4) have been cup jointed at the top of culture dish (3), the bottom of culture dish (3) is provided with first adjustment mechanism (5), just the bottom of first adjustment mechanism (5) is provided with second adjustment mechanism (6).

2. The quantitative detection device for the skin cell metabolism velocity according to claim 1, wherein the first adjusting mechanism (5) comprises a placing frame (501), a sliding groove (502), a limiting shaft (503), a supporting shaft (504), a first servo motor (505), a first threaded rod (506), a first connecting plate (507) and a mounting plate (508), the placing frame (501) is located at the bottom of the culture dish (3), and the placing frame (501) is sleeved with the culture dish (3).

3. The quantitative detection device for the metabolism velocity of skin cells according to claim 2, wherein sliding grooves (502) are symmetrically formed in two sides of the placement frame (501), limiting shafts (503) are symmetrically arranged inside the sliding grooves (502), supporting shafts (504) are symmetrically arranged on two sides of the placement frame (501), the supporting shafts (504) are n-shaped, the supporting shafts (504) penetrate through the sliding grooves (502) and extend to the inside of the second adjustment mechanism (6), the supporting shafts (504) are sleeved with the limiting shafts (503), and the supporting shafts (504) and the limiting shafts (503) are vertically distributed.

4. The quantitative detection device for the skin cell metabolic rate according to claim 3, wherein a mounting plate (508) is arranged between two groups of support shafts (504), a first servo motor (505) is arranged at the top of the mounting plate (508), a first threaded rod (506) is arranged at the output end of the first servo motor (505), a first connecting plate (507) is connected to the outer wall of the circumference of the first threaded rod (506) in a threaded manner, and the top of the first connecting plate (507) is fixedly connected with the bottom of the placing frame (501).

5. The quantitative detection device for the skin cell metabolic rate according to claim 1, wherein the second adjusting mechanism (6) comprises a second servo motor (601), a second connecting plate (602), a second threaded rod (603), two groups of guide rails (604) and a support plate (605), the two groups of guide rails (604) are arranged and are symmetrically distributed about the placement frame (501), and the guide rails (604) are matched with the support shaft (504).

6. The quantitative detection device for the skin cell metabolic rate according to claim 5, wherein a support plate (605) is arranged between two sets of guide rails (604), a second servo motor (601) is arranged on the top of the support plate (605), a second threaded rod (603) is arranged at the output end of the second servo motor (601), a second connecting plate (602) is connected to the outer circumferential wall of the second threaded rod (603) in a threaded manner, and the top of the second connecting plate (602) is fixedly connected with a mounting plate (508).