RU130884U1 - CENTRIFUGE REFRIGERATOR FLOOR FOR SEPARATION OF BLOOD AND BIOMATERIALS - Google Patents

Abstract

1. Floor refrigerated centrifuge for separation of blood and biomaterials at low temperatures, including a heat-insulated chamber located in the upper part of the housing under the lid, covered by a coil connected to the refrigeration unit, a bucket-rotor located in the chamber cavity, rotatably placed in the chamber cavity and connected with an electric motor shaft, the housing of which is connected to an axis supporting the ball head, located in the cavity of the damper, consisting of a stationary housing filled with a viscous fluid, and a movable element with a central hole in which the ball head is placed, while the fixed damper body is rigidly fixed to the body core, and its movable part is rigidly connected to the lower part of the electric motor to move the movable damper element in the horizontal plane with vibration of the electric motor rotor, characterized in that a vertically oriented motor housing is mounted on a horizontally located plate, which is attached to the frame of the housing under the camera, with which the racks are rigidly with Yazan fixed casing of the damper, so as rigidly associated with a support on the bottom of the core korpusa.2. The centrifuge according to claim 1, characterized in that the base of the housing is mounted on wheels and equipped with supports with a screw mechanism for pushing them all the way into the support base to fix the housing from movement. The centrifuge according to claim 1, characterized in that the lid is thermally insulated and is equipped with a locking mechanism for fixing it in a closed state on the housing for sealing the bucket-rotor cavity and a telescopic air damper for holding

Description

The utility model relates to the field of medical technology and relates to the design of a refrigerated centrifuge ЦРН 4-04 designed to separate blood and suspensions at low temperatures with particle sizes from 0.1 to 10 microns into components under the action of a centrifugal rotor field. The centrifuge can be used at blood transfusion stations, in blood departments of hospitals, clinics, hospitals, in laboratories of medical institutions, in medical research institutes, and also for carrying out separation of suspensions in biotechnology, biology, chemistry, physics and other fields of industry and science.

Centrifuging blood to obtain samples of serum, plasma or blood cells is one of the time-consuming and important stages of the pre-analytical period of clinical laboratory research. To obtain serum or blood plasma in clinical laboratories, preparative (laboratory) centrifuges of general purpose with various types of rotors are used, which make it possible to select the necessary centrifugal acceleration by controlling its rotation speed (from 1000 to 25000 rpm).

In centrifuges without cooling, the rotor plays the role of a fan during its rotation. Room air is sucked into the working chamber of the centrifuge, washes a rotating rotor and is thrown out through special openings. However, with such natural cooling, the temperature of the rotor and, therefore, the shared sample increases. The heating of the sample increases with increasing speed of rotation of the rotor and the duration of centrifugation, depending on the design of the centrifuge, the type of rotor, the volume of the sample, and other factors.

A known centrifuge for blood fractionation, containing a chamber with a rotor located in it, connected to an electric motor mounted on a suspension, including a damper, consisting of a housing having a cylindrical cavity filled with a viscous fluid into which a movable element is immersed (technical data sheet of a centrifuge TsLPZ- 3.5 pp. 9, 1998).

This technical solution reduces the level of vibration of the rotor to acceptable values. However, the practical implementation of this solution is difficult, because it requires the use of special racks of large diameter to install the damper.

In addition, there should be three such dampers, at least in order to ensure their symmetrical arrangement around the electric motor. Moreover, the placement radius of these racks exceeds the radius of the drive motor by more than 2 times. All this significantly increases the dimensions of the described centrifuge assembly. In this case, the dampers are installed on the said racks and are connected to the motor housing by means of rubber buffers. The latter is a significant drawback, since the possibility of rupture or cracking in the buffer (due to aging of the rubber) can lead to an emergency increase in the level of vibration of the rotor. If the specified defect occurs at a high rotor speed, this can lead to breakage of either the rotor or the bearings of the electric motor. All this reduces the reliability of the centrifuge as a whole.

A centrifuge for blood fractionation is also known, including a chamber, a rotor installed in it, mounted on an electric motor shaft, and a damper consisting of a housing filled with a viscous liquid and a movable element having a central hole (US No. 3606143, 233-23, 09/20/1971 )

In this centrifuge, the damper is located under the chamber, and in the damper body there is a central hole through which the motor shaft passes. This hole is sealed with special gaskets. The damper body is filled with a viscous fluid into which a movable element having a central hole and representing a plate with protrusions is immersed. The damping of the vibrations of the centrifuge rotor arising from its imbalance occurs due to the flow of viscous fluid along the “maze” formed by the indicated protrusions of the plate. This principle allows only minor rotor vibrations to be damped. In the case of an increase in the imbalance of the centrifuge rotor and, consequently, an increase in its vibration level, this damper design will not provide a decrease in the vibration level of the rotor to safe values. The consequence of this is a decrease in the reliability of the centrifuge. In addition, the design of the centrifuge is complicated due to the placement of the damper under the centrifuge chamber.

Through the vent holes of the centrifuge, together with the air, substances are released that are in the working chamber of the centrifuge. Therefore, air flows should not be directed at people, and when working with samples containing infectious agents, special safety measures must be observed.

When preparing blood samples for the study of thermosensitive analytes (ACTH, insulin, C-peptide, parathyroid hormone, homocysteine, etc.), the natural cooling of the rotor is not enough and it is required that the temperature of the sample to be separated is no higher than 2-4 ° C. In this case, it is necessary to use a centrifuge with an integrated compression refrigerator, which reduces the temperature in the working chamber. The required sample temperature is set by the operator and controlled by a centrifuge control system. In practice, such centrifuges are usually called refrigerated.

A known centrifuge for blood fractionation, including a chamber, a bucket-rotor placed in it, mounted on an electric motor shaft, and a damper, consisting of a housing filled with a viscous fluid, and a movable element having a central hole, the damper is equipped with a spherical finger, the spherical part of which is located in the specified hole of the movable element, and the cylindrical part of the ball pin is connected with the lower cover of the motor to move the movable element in the horizontal plane with vibration of the rotor. The refrigeration unit is connected with a coil mounted on the outside of the chamber (RU No. 2198035, B04B 5/02, B04B 9/12, publ. 02/10/2003).

The disadvantage of this solution is that the fastening of the motor casing in the damper to the support element in the lower part of the casing and with separate damping in the upper part at the point of attachment of the rotor shaft to the bucket-rotor does not provide damping of vibrations of both the motor casing and its rotor relative to corps. This does not allow fractionation (separation) of the biomaterial at high speeds, for example, up to 4000 min ^-1 .

This utility model aims to achieve a technical result, which consists in increasing the reliability of the centrifuge by reducing the vibration level of the rotor of the electric motor to safe values, regardless of speed.

The specified technical result is achieved in that in a refrigerated floor centrifuge for separation of blood and biomaterials at low temperatures, including a heat-insulated chamber located in the upper part of the housing under the lid, covered by a coil connected to the refrigeration unit, a bucket-rotor placed in the chamber cavity, located in the cavity cameras with the possibility of rotation and connected with the shaft of the electric motor, the housing of which is connected to the axis bearing the ball head, located in the cavity of the damper, consisting of a movable housing filled with a viscous fluid, and a movable element with a central hole in which the ball head is located, while the fixed damper housing is rigidly fixed to the core of the housing, and its movable part is rigidly connected to the lower part of the motor to move the movable damper element in the horizontal plane when vibration of the rotor of the electric motor, a vertically oriented motor housing, is mounted on a horizontally located plate, which is attached to the body frame under the cam swarm, with which the uprights are rigidly associated fixed casing of the damper, so as rigidly associated with a support on the bottom of the core body.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present utility model is illustrated by a specific example of execution, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result.

Figure 1 is a General view of a floor centrifuge;

figure 2 is a longitudinal section aa in figure 1;

figure 3 is a top view of a centrifuge with the cover removed;

4 is a block of the suspension of the electric motor.

According to this utility model, the design of an outdoor refrigerator centrifuge is considered, designed to perform the functional task of centrifuging blood to obtain high-quality samples of serum, plasma and other suspensions (biomaterial) with particle sizes from 0.1 to 10 microns. The principle of operation of the centrifuge is based on the separation of blood and suspensions (biomaterial) with particle sizes from 0.1 to 10 microns into components under the action of the centrifugal field of the rotor both at low temperatures (minus 20 ° C) and high temperatures (plus 40 ° C) .

Floor refrigerated centrifuge for separation of blood and biomaterials at low temperatures (Figs. 1-4) includes a heat-insulated chamber 3 located in the upper part of the housing 1 under the lid 2, enclosed by a coil 4 in communication with the refrigeration unit 5, which is mounted in the cavity of the lower part housings (compressor 6, cooling radiator 7, switching relays, etc.). The base of the housing is mounted on wheels 8 (for transportation / movement by rolling) and is equipped with supports 9 with a screw mechanism for their extension until it stops in the support base to fix the housing from movement.

The cover 2 is made L-shaped, one part 10 of which, when the cover is in the closed position, is placed above the chamber 3 and tightly closes it, and the other bent 11 is pivotally connected to the housing 1. The cover is thermally insulated 12 (foam rubber or other material used to create sealing insulating coatings) and equipped with a locking mechanism 13 for fixing it in a closed state on the housing for sealing the cavity of the bucket rotor 14 and telescopic / mi pneumatic damper / ramie 15 to hold the lid in the tilted position. The use of the lid of such a curved design is due to the fact that as much as possible to open the space above the bucket-rotor and not interfere with the placement or removal of containers from the camera.

Under the cover in the upper part of the housing in the area separated from the rest of the housing in the cavity of the chamber with the possibility of balanced rotation placed bucket-rotor 14, made with sockets 16 for laying containers with biomaterial. The centrifuge uses the following containers to separate substances into components: 4 plastic containers of the Gemakon type 500/300 or similar, 4 bottles of 250 ml or 500 ml of type I and II GOST 10782.

The rotor bucket is connected with the shaft of an electric motor 17, the housing of which is connected to an axis 18 carrying a ball head located in the cavity of the damper 19. This damper consists of a stationary body filled with a viscous fluid, and a movable element with a central hole in which the ball head is located axis 18. The design of the damper repeats the damper according to the prototype. By the principle of operation, such a damper refers to hydraulic dampers. In the absence of deviation of the rotor of the electric motor from the vertical axis, the coaxial axis of the rotor and the axis of communication of the rotor with the bucket-rotor, the movable element located inside the fixed damper body does not move and is balanced on all sides by the pressure of a viscous fluid. When a deviation of the rotor axis from the indicated coaxial coincidence of the axes occurs, the axis 18 is angularly displaced, resulting in the decomposition of forces in the contact zone of the ball head and the movable element, as a result of which this movable element tries to shift in the transverse direction inside the bath. But this displacement provokes the appearance of friction in the layers of a viscous fluid, in which the gradient of the displacement of the layers of viscous fluid is less than the displacement gradient of the movable element. There is a braking effect of the movable element, in which the appearance of an angular deviation of the axis of the rotor of the electric motor does not lead to the actual angular deviation of this si or, in any case, limits this deviation. As a result, when rotating at high speeds, the bucket-rotor-electric motor system acquires a balanced rotation of the bucket-rotor.

In the construction according to the utility model, the fixed damper housing is rigidly fixed to the body core, and its movable part is rigidly connected to the lower part of the electric motor to move the movable damper element in the horizontal plane during vibration of the electric motor rotor. The fixed body of the damper was mounted at two spaced points on the skeleton. The vertically oriented motor housing 17 is mounted on a horizontally located plate 20, which is attached to the body shell under the camera 3, with which the posts 21 are rigidly connected to the fixed housing of the damper 19, which is also rigidly connected to the support 22 on the lower part of the body shell.

Improving the reliability of the centrifuge by reducing the vibration level of the rotor of the electric motor to safe values, regardless of speed, is provided by spacing the support for the perception of reactive moment on the core of the centrifuge. In the prototype, fixing the damper only at the lower point of the body frame led to an unbalanced system, since it was this fixing point that was the support of the reactive moment from the unbalanced operation of the electric motor during rotation of the bucket rotor. In the utility model there are two such points and they are spaced vertically, which ensures the separation of the reactive moment and the impact on each such attachment point with half the load effect.

A block 23 with components and electronic components for controlling the operation modes of the main centrifuge units is mounted inside the housing. A panel 24 with controls 25 is mounted on the side of the housing.

The following controls are displayed on panel 21:

- to control the temperature inside the chamber (the range of setting the temperature in the chamber is from minus 20 ° С to plus 40 ° С);

- to control the speed of rotation of the bucket-rotor (the range of the frequency of rotation of the rotor of the cross bucket-rotor is from 500 min ^-1 to 4000 min ^-1 ).

- control of the logical connection between temperature modes and bucket-rotor revolutions within the framework of the following algorithm:

(the range of preset stabilized temperatures in the chamber should be at ambient temperature from 10 to 25 ° C:

- up to minus 20 ° С at a rotor speed of 1500 min ^-1 , no more;

- up to minus 10 ° С at a rotor speed of 2500 min ^-1 , not more than;

- up to 0 ° С at a rotation frequency of 3300 min ^-1 , no more;

- from plus 5 ° C or more at a rotation frequency of from 3000 to 4000 min ^-1 .

the range of preset stabilized temperatures in the chamber at an ambient temperature of 25 to 40 ° C; the lower limit of the temperature stabilization range tH, ° C for all rotor speeds is determined by the formula:

δn1 = kf _max -n _ass (1)

Where

f _max - pulse repetition rate from the sensor, measured by the frequency meter, maximally different from the set value, Hz

k - dimensional coefficient equal to 60/24 (Hz · min) - ¹

n _ass - the set value of the rotor speed, min- ¹

In addition, in block 21, automation tools are provided that perform the following functions:

a) providing automatic braking of the rotor when exceeding the maximum permissible speed of more than 100 min ^-1 ;

b) turning off the temperature control system and reducing the rotor speed to a stop when the indicator in the chamber reads plus (43 ± 1) ° С or minus (23 ± 1) ° С; or deviation of the temperature in the chamber from the set ± 5 ° C.

c) transfer of the centrifuge to the braking mode and display on the DISBALANCE indicator with a mass difference of glasses diametrically located in the rotor above 30 g.

d) the exclusion of the possibility of starting the centrifuge with the chamber lid open and the possibility of opening the chamber lid until the rotor stops completely.

e) remembering the last used program when the power is turned off (non-volatile memory).

All information about the set parameters and current indicators are informationally displayed on the liquid crystal monitor 26 of the panel 24.

Claims (5)

1. Floor refrigerated centrifuge for separation of blood and biomaterials at low temperatures, including a heat-insulated chamber located in the upper part of the housing under the lid, covered by a coil connected to the refrigeration unit, a bucket-rotor located in the chamber cavity, rotatably placed in the chamber cavity and connected with an electric motor shaft, the housing of which is connected to an axis supporting the ball head, located in the cavity of the damper, consisting of a stationary housing filled with a viscous fluid, and a movable element with a central hole in which the ball head is placed, while the fixed damper body is rigidly fixed to the body core, and its movable part is rigidly connected to the lower part of the electric motor to move the movable damper element in the horizontal plane with vibration of the electric motor rotor, characterized in that a vertically oriented motor housing is mounted on a horizontally located plate, which is attached to the frame of the housing under the camera, with which the racks are rigidly with Yazan fixed casing of the damper, so as rigidly associated with a support on the bottom of the core body. 2. The centrifuge according to claim 1, characterized in that the housing base is mounted on wheels and equipped with supports with a screw mechanism for pushing them all the way into the support base to fix the housing from movement. 3. The centrifuge according to claim 1, characterized in that the lid is thermally insulated and equipped with a locking mechanism for fixing it in a closed state on the housing for sealing the bucket-rotor cavity and a telescopic air damper to hold the lid in the tilted position. 4. The centrifuge according to claim 1, characterized in that the lid is L-shaped, one part of which, when the lid is closed, is placed above the camera, and the other, hinged, is hingedly connected to the housing. 5. The centrifuge according to claim 1, characterized in that a panel with controls is mounted on the side of the housing.

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