RU72135U1 - EXIT BLOOD TRANSFUSION STATION - Google Patents

Abstract

1. A mobile blood transfusion station containing a vehicle in the cabin of which are thermostats with heat-insulated working chambers for storing polymer bags filled with blood taken from the donor blood or its components, at temperatures determined by regulatory documents as long-term storage temperatures of the selected type of blood components at the same time, cooling devices with the possibility of lowering the temperature of the substance inside the polymer bags before their placement in the working chambers of the thermostats within the time period specified by regulatory documents. 2. The visiting blood transfusion station according to claim 1, characterized in that the cooling devices are made in the form of express coolers of a batch of filled polymer bags with the possibility of lowering the temperature of the substance in them from an initial temperature of 37 ° C to 4 ° C or 22 ° C in a time exceeding 15 min. 3. The visiting blood transfusion station according to claim 1, characterized in that the cooling devices are made in the form of express freezers with the possibility of reaching inside the filled polymer bags a temperature of no higher than minus 30 ° C in a time not exceeding 1 hour. 4. The visiting blood transfusion station according to claim 1, characterized in that it contains cold elements, the working substances in which are selected with phase transition temperatures below the storage temperatures of the corresponding types of blood components, freezers for freezing cold elements, thermal containers for storing and temporary storage of frozen cold elements, thermostats are made in the form of thermal containers, work

Description

The utility model relates to the field of medical equipment, and specifically to mobile points for the collection of donated blood and its components in on-site conditions.

The closest in technical essence and the achieved result to the proposed device is an exit blood transfusion station containing a vehicle, the cabin of which contains thermostats with heat-insulated working chambers for storing containers filled with donated blood or blood components taken at the exit at temperatures defined by regulatory documents as long-term storage temperatures of the selected type of blood components. Utility model of the Russian Federation 3689, 1997.

The disadvantages of the known device are, firstly, the low biological usefulness of the components of the donated blood harvested on the road, and, secondly, the high value of the power consumed by the devices included in the device’s package, designed to temporarily maintain temperature conditions

storage of blood components during their transportation to a stationary institution.

These disadvantages are due to the following reasons.

In the known device, the containers, after filling them with blood or its components, are immediately placed in the working chambers of the thermostats in which the temperature control mode is maintained corresponding to the long-term storage temperatures of the components defined by regulatory documents, for example, Recommendations of the Council of Europe Guidelines for the Preparation, Use and Quality Assurance of Blood Components, a number of orders of the Ministry of Health of the Russian Federation. In this regard, the duration of transient non-stationary processes of cooling containers with blood components from the initial temperature equal to the normal temperature of the human body to the final temperature It turns out to be extremely large, practically the transportation of blood components to a stationary institution is carried out at very uncertain temperature conditions that completely do not meet the established requirements.

As noted in the Manual for doctors “Blood preparation in the field” (EB Zhiburt, V.E. Alekseev, S.K. Sidorov. SPC Intelforum. M. 2005, p. 72-73), one of the main reasons not only the deterioration of biological indicators taken at the exit of blood components, namely, their complete deterioration and impossibility of subsequent use, is:

- lack of blood cooling before transportation;

- non-compliance with the temperature regime of storage of components during transportation.

In addition, in the known device to maintain a given mode, semiconductor thermal modules are used that implement the Peltier effect, having a low coefficient of conversion of electric power to refrigeration. So, while maintaining the temperature control mode in the working chamber at a level lower than the external temperature by (25-30) ° С, the electric conversion coefficient

the power supplied to the thermal modules to the refrigerating capacity does not exceed 10%, therefore, the required value of the electric power with a working chamber volume of ~ 100 dm ³ is (150-200) W. In this regard, the use of a known device for the temporary storage of biomedical thermosensitive materials during transportation is associated with the need to use sufficiently powerful power sources, which in some cases is very problematic.

The technical problem solved by the utility model is to increase the degree of biological usefulness of blood components taken under field conditions by ensuring full compliance with the established regulatory requirements for the temperature and time parameters of processes implemented in the components of substances as in non-stationary thermal processes during thermal (cold) processing, as well as in stationary processes implemented in a stored substance during transportation to a stationary medical institution, as well as reduction in energy consumption when driving a vehicle.

The specified technical result is achieved by the fact that the exit blood transfusion station contains a vehicle, in the cabin of which there are thermostats with thermally insulated working chambers for storing polymer bags filled with donated blood or its components taken at the exit, at temperatures defined by regulatory documents as the temperature of long-term storage of the selected type of blood components, while cooling units are introduced into the exit station with the ability to lower the temperature of the substance inside the polymer bags to before they are placed in the working chambers of the thermostats within the time period specified by regulatory documents.

Cooling devices can be made in the form of express coolers of a batch of filled polymer bags with

the possibility of lowering the temperature of the substance in them from an initial temperature of 37 ° C to temperatures of 4 ° C or 22 ° C in a time not exceeding 15 minutes

Cooling devices can be made in the form of express freezers with the possibility of reaching inside the filled polymer bags a temperature of no higher than minus 30 ° C in a time not exceeding 1 hour.

Cold elements were introduced into the site of the blood transfusion station, the working substances in which were selected with phase transition temperatures lower than storage temperatures the corresponding types of blood components, freezers for freezing cold elements, thermal containers for placing and temporary storage of frozen cold elements, thermostats are made in the form of thermal containers, the working chambers of which are connected to the cold elements with the possibility of compensating for the heat fluxes passing from the outside through the insulation into the working chamber due to the heat of the phase transition of the working substance in cold elements.

The essence of the utility model is illustrated by drawings, which depict on:

figure 1 schematically in terms of the technological department, which is part of the proposed visiting station blood transfusion;

figure 2 - thermal container-thermostat for storing pre-chilled or frozen blood components;

figure 3 - two-chamber apparatus, in the upper part of which a thermostat is made to maintain normal temperature of the human body, and in the lower part is made express cooler of donor blood and its components;

figure 4 - freezer for freezing cassettes with blocks of cold elements;

5 is a cassette for placing a block of cold elements;

6 is a styling for placing filled polymer bags.

Consider the most common embodiment of an on-site blood transfusion station that implements the so-called "technologically" complex medical-tactical scheme, as a result of which various blood components are harvested on-site - directly donated blood, erythrocyte mass, platelet mass, plasma.

In a generalized version, the proposed blood transfusion station includes a vehicle, a fragment of the passenger compartment 1 of which, which is a technological compartment 2, is shown in FIG. There are donor chairs (not shown in the drawing), several tables and chairs (not shown in the drawing) used in registration and medical examination of donors, when issuing tea to them, etc., a set of instruments and accessories used in acts donations, such as sets of syringes, test preparations, sterilization materials, scales, sealers of plastic bags with blood, cash register, etc. (not shown in the drawings).

In technological department 2, a centrifuge 3 is installed (depending on the volume of preparations of blood components, specifically plasma, the number of centrifuges can reach several pieces), express plasma freezer 4 obtained from freshly prepared donor blood by centrifugation, a two-chamber apparatus 5, in the upper part of which is made thermostat 6, in the working chamber 7 of which a temperature regime is maintained close to the normal temperature of the human body (+ 37 ° C), and an express cooler 8 is made in the lower part, in eyes chamber 9 which ensures rapid temperature drop batch polymeric packages 10 filled with donor blood or its components, as well as a package 11 with thermophysical simulator blood, inside which is placed a temperature sensor 12, to temperatures of certain regulations as temperature long storage t _xp donor blood and its components, thermal containers-thermostats 13, in the working chambers 14 of which

storage at various temperatures is provided defined by regulations, various types of blood components. For example, one thermo-container-thermostat 13 is configured for storage temperature (storage of polymer bags 10 with donated blood or red blood cells), the second temperature (storage of platelet mass), finally, the third thermal container - to temperature (storage of packages 10 with frozen plasma), etc. The technological department has a freezer 15 for freezing cassettes 16 with cold elements 17, a thermal container 18 for storing cassettes 16 with a block of frozen cold elements 17, table 19, chair 29.

The choice of working substances for the cold elements 17 is determined so that the temperature of their phase transition would be lower than the storage temperature of the selected type of blood components.

So, if you need to store donated blood or red blood cells at a temperature use a working substance with a phase transition temperature close to 0 ° C, and if necessary, store frozen plasma at a temperature low-temperature cold elements 17 are used, the working substance of which has a phase transition temperature in the range of minus (34 ÷ 46) ° С.

The package of the proposed traveling blood transfusion station also includes piling 21 for placing filled polymer bags 10.

To connect the blocks of frozen cold elements to the working chambers 14 of the thermo-containers-thermostats 13, heat-conducting circuits with automatically adjustable (if necessary) thermal resistance are used.

In thermo-containers-thermostats 13, designed for temporary storage of packages 10 with frozen plasma at temperatures minus (25 ÷ 30) ° С, the heat-conducting circuit is transformed into direct cold

the effect of frozen low-temperature cold elements, the phase transition temperature of the working substance of which is minus (34 ÷ 46) ° C, directly placed in the working chambers 14.

In a specific embodiment of thermostat containers-thermostats 13, designed for temporary storage of pre-cooled to temperatures , eg, or filled polymer bags 10, the heat-conducting circuit is made in the form of an air stream with automatically controlled circulation intensity created between the working chamber 14 and the block of frozen cold elements 17.

For this purpose, fans 22 are included in this type of thermal containers-thermostats 13, inputs connected to the outputs of the power supply (not shown in the drawing), automatically controlled by signals from a temperature sensor 23 located in the working chamber 14, the outputs of which are connected to the control inputs the temperature control unit (not shown in the drawing) and with the inputs of the temperature indicator 24, radiators 25, between the bases of which there are cassettes 16, with blocks of frozen cold elements 17, air ducts 26, through which the autonomous compartment 27, in which the cassettes 16 with the cold elements 17 are located, communicates with the volume of the working chamber 14, the shutters 28 installed in the ducts 26.

Moreover, the placement of the compartment 27 in the lid of the thermocontainer-thermostat 13 is optional; structurally, the compartment 27 can be located in the lower part of the thermal container of the thermostat 13, on the side behind it and, in general, can be made as a separate autonomous unit.

The proposed site blood transfusion works as follows.

Pre-connected to the mains power supply, for example, by means of a network cable with an external outlet (not shown in Fig.), A centrifuge 3, express plasma freezer 4, thermostat 6 and

express cooler 8, structurally formed in a two-chamber apparatus 5 to save space in the technological compartment 2 of the vehicle interior 1, freezer 15, lighting devices, the entire set of devices used in donation acts.

The power supply units of thermostat containers-thermostats 13 are connected to the on-board power supply system, by means of which the thermal resistance of the heat-conducting circuits between the working chambers 14 and the blocks of frozen cold elements is regulated, for example, the operation of the fans 22.

The operator in the technological department 2 stacks the cold elements 17 in the cassettes 16. The blocks of the cold elements 17 thus formed are placed in the working chamber of the freezer 15 for freezing.

Frozen blocks of refrigerant elements 17 by means of a heat-conducting circuit with automatically adjustable thermal resistance (for example, in the form of an air stream with automatically controlled circulation intensity) are connected to the working chambers of thermo-containers-thermostats 13, ensuring the maintenance of temperatures in them .

Temperature control in the working chambers 14 of thermal containers-thermostats 13 is carried out by a digital indicator 24 in accordance with the signals of the temperature sensor 23 installed in the working chamber 14; when the temperature in the working chamber 14 exceeds the limits determined by the threshold settings, the light and sound alarms are triggered (not shown in the drawing).

At a temperature in the working chamber 14, determined by signals from the sensor 23, exceeding the value of t _article , the control unit (not shown in the diagram) connects the fans 22 to the power supply. The air flow generated by the fans 22 passes through the radiators 25, is cooled and, entering the working chamber 14 through the ducts 26, causes it

cooling. The position of the flaps 28 in the ducts 26 corresponds to their open state.

When the temperature in the working chamber 14 is equal to t _st -δt _st , where δt _st is the accuracy of temperature stabilization, the control unit disconnects the fans 22 from the power supply. The circulation of the air flow in the ducts 26, both forced and natural (the shutters 28 block the ducts 26) is stopped. Under the action of the heat flux passing from the outside through the heat barrier of the working chamber 14, the temperature of the sensor 23 placed in it rises to t _st + δt _st ; in accordance with the signals received from it, the control unit reconnects the fans 22 to the power supply. In the future, the above steps of the operation of thermostat containers 13 are periodically repeated.

Surplus frozen blocks of refrigerant elements 17 in cassettes 16 are placed in a thermal container 18 for temporary storage.

The polymer bags 10, filled with blood after the acts of donation, are transferred to the operator in the technological department 2 on the table 19. The operator at the beginning places them in stacks 21, and then stacks 21 with bags 10 in the working chamber 7 of thermostat 6.

When 21 batches are accumulated in a packing from a given number of packets 10, for example, 20 pieces, packing 21 together with a polymer bag 11 filled with a substance that is a thermophysical simulator of donated blood is removed from the working chamber of the thermostat 16 and placed in the working chamber 9 of the express cooler 8 while connecting the cable output of the temperature sensor 12, located inside the package 11, to the input of the control unit express cooler 8 (Fig. the control circuit of the apparatus is not shown).

Upon reaching temperature inside the filled polymer bags 10, determined by the signals of the temperature sensor 12 installed in the bag 11 with a thermophysical simulator, removed from

the working chamber 9 of the express cooler 18 laying 21 with a batch of polymer bags 10 filled with donated blood, cooled to . At the same time, in the working chamber 9 of the express cooler 8, such mode parameters of the cooling process are provided, for example, a high heat transfer rate on the outer surface of the polymer bag 10, realized by creating a high air circulation rate, using finned bag holders, mixing the substance inside the bags 10 by setting them in motion with acceleration periodically changing in magnitude and direction, as well as maintaining the temperature of the air flow at a level lower in which in the substance of each polymer bag 10 rather quickly, in a time not exceeding 15 minutes, the temperature is reached determined by the signals of the temperature sensor 12 located in the substance of the thermophysical simulator 11. The cable output of the temperature sensor 12 in the simulator 11 is disconnected from the electric circuit of the express cooler 8, and the simulator 11 is again placed in the working chamber 7 of the thermostat 6, where its temperature begins to rise from to normal temperature of the human body, i.e. up to 37 ° C.

Stacking 21 chilled to packages 10 are placed in the working chambers 14 of thermal containers-thermostats 13, the temperature in which by means of blocks of cold elements 17 previously reduced to and further maintained at this level.

Subsequently, as new batches of polymer bags 10 with donated blood arrive, the procedures described above are repeated, the operator in the technological department 2 sequentially fills the working chambers 14 of thermostatic containers-thermostats 13 with stacks 21 with packages 10 pre-cooled in the express cooler 8.

When the temperature in the working chamber 14 of the thermal container-thermostat 13, increasing due to heat influx from the outside, reaches the set

threshold value, sound and light alarm will be triggered. This indicates that the working substance in the cold elements 17 passed from a solid phase to a liquid state.

The operator removes the cassette 16 with the spent refrigerant block 17, removes another cassette 16 from the working chamber of the thermocontainer 18 with the frozen cold cell block 17 and connects them to the working chamber 14 of the thermocontainer-thermostat 13. When the vehicle of the blood transfusion station is parked and it is possible to connect the entire equipment of the item to the power supply, the cassette 16 with the block of spent cold elements 17, the operator places in the working chamber of the freezer 15 for a new act of freezing. When the vehicle is moving, cassettes 16 with the spent refrigerant block 17 are placed on a rack (not shown in the drawing). When designing an exit blood transfusion station, the capacity of the working chamber of the freezer 15, the number of cassettes 16 with the blocks of cold elements 17 are calculated in such a way as to maintain the temperature conditions in the working chamber 14 of the thermal container-thermostat 13 at the level during the entire process of returning the item to an inpatient medical facility.

When harvesting blood components, storage temperature which, defined by regulatory documents, are in the range of negative values, for example, plasma, the storage temperature of which is in the range of minus (30 ÷ 40) ° С, as devices for lowering the temperature to use quick freezers 4.

In this case, low-temperature modifications of cold elements 17 are used, the working substance of which has a phase transition temperature below .

Cassettes 16 with a block of low-temperature cold elements 17 are pre-frozen in the working chamber of the freezer 15.

Then, the cassettes 17 with blocks of frozen low-temperature cold elements 17 are connected to the number of working chambers 14 of thermostatic containers 13, which are planned to be loaded with low-temperature blood components taken at the exit.

In this case, the temperatures of the working chambers are reduced to t _k ≤t _xp , where t _k is the temperature of the working chamber.

The polymer bags 10 with plasma obtained after fractionation of freshly prepared donor blood, carried out by means of centrifuges 3, are placed in the working chamber of the express freezer 4, where they are frozen and cooled to a temperature of t _xp , not exceeding minus 30 ° С. Moreover, for the purpose of freezing, such devices 4 are used that previously, at the stage of medical-technical testing, confirmed the possibility of reaching a temperature of no higher than minus 30 ° C in the center of the plasma package in a time not exceeding 1 hour. Such requirements for the temperature-time parameters of the freezing process are determined by a number of regulatory documents, for example, by order of the Ministry of Health of the Russian Federation No. 193 of May 7, 2003, recommendations of the Council of Europe Guidelines for the preparation, use and quality assurance of blood components. Next, the operator removes the polymer packets 10 with frozen plasma having a temperature t _xp from the working chamber of the express freezer 4, places them in the stack 21 and then puts the stack 21 in the working chamber 14 of the thermo-container-thermostat 13, in which the temperature not exceeding the required level has already been reached plasma storage temperature.

The process of maintaining negative temperature values in the working chamber 14 of the thermocontainer-thermostat 13, carried out by means of cassettes 16 with a block of low-temperature cold elements 17, the order of block recharging and re-restoration of cold elements 17 after the transition of the working substance from solid to liquid are similar to those described above.

Thus, the introduction of blood transfusion apparatus to the site of the blood transfusion apparatus to quickly lower the temperature of blood components to t _xp , such as express cooler 8 and express freezer 4, can drastically reduce the duration of transient unsteady processes, which is one of the first necessary conditions to ensure a high degree of biological the usefulness of harvested blood components.

On thermo-containers-thermostats 13, in which packages 10 with blood components are placed, the temperature of which has already been brought up to , the functions are assigned only to maintain this temperature with the required accuracy, and not the function of ensuring any values of the time parameters of non-stationary processes.

In this regard, the introduction of a freezer 15 blood transfusion to the site of the blood transfusion station for freezing cold elements 17 of various modifications, the temperature of which the phase transition of working substances is lower , as well as a thermal container 18 for storing cassettes 16 with blocks of frozen refrigerant elements 17, in combination with the provided possibility of their quick reloading of thermo-containers-thermostats 13, avoids the need to connect any heating equipment with a high level of energy consumption directly to the vehicle’s electrical network.

In the proposed exit blood transfusion station, all energy-intensive operations associated with dosed cold exposure on packages 10 with harvested blood components, with the generation of low-grade thermal power and its subsequent accumulation in low-temperature cold elements, are carried out at the station site, in the place of blood collection.

Therefore, in the proposed visiting station for blood transfusion, ensuring the maintenance of the required temperature

working chambers 14 of thermal containers-thermostats 13 at boils down only to the compensation of heat fluxes through the insulating fence on the previously accumulated thermal energy of the cold elements 17.

In turn, the above not only causes a sharp decrease in the total energy consumption of the exit station during movement, but also significantly increases the integral reliability of the complex, and, as a result, guarantees high values of the criteria that determine the biological usefulness of the taken components of donated blood.

Claims (4)

1. A mobile blood transfusion station containing a vehicle in the cabin of which are thermostats with heat-insulated working chambers for storing polymer bags filled with donated blood or its components taken at the exit, at temperatures

defined by regulatory documents as the temperature of long-term storage of the selected type of blood components, while cooling units are introduced into the exit station with the ability to lower the temperature of the substance inside the polymer bags to

before they are placed in the working chambers of the thermostats within the time period specified by regulatory documents. 2. Visiting blood transfusion station according to claim 1, characterized in that the cooling devices are made in the form of express coolers of a batch of filled polymer bags with the possibility of lowering the temperature of the substance in them from an initial temperature of 37 ° C to 4 ° C or 22 ° C over time not exceeding 15 minutes 3. The visiting blood transfusion station according to claim 1, characterized in that the cooling devices are made in the form of express freezers with the possibility of reaching inside the filled polymer bags a temperature of no higher than minus 30 ° C in a time not exceeding 1 hour. 4. Visiting blood transfusion station according to claim 1, characterized in that it contains cold elements, the working substances in which are selected with phase transition temperatures below storage temperatures

the corresponding types of blood components, freezers for freezing cold elements, thermal containers for placing and temporary storage of frozen cold elements, thermostats are made in the form of thermal containers, the working chambers of which are connected to the cold elements with the possibility of compensating for the heat fluxes passing from the outside through the insulation into the working chamber due to the heat of the phase transition of the working substance in cold elements.