RU2228494C1 - Thermostat for biological substance storage - Google Patents

Abstract

FIELD: portable devices using cold-storage bodies. SUBSTANCE: thermostat comprises body with door and lock. Work chamber formed of corrosion-resistant material is arranged into body and separated from body by heat-insulation layer. Thermostat has thermoelectric unit for work chamber heating made as three distributed electric heating members, control unit located in individual body, temperature sensors arranged outside working chamber, temperature controller, indicators, continuous current generator, amplifier, comparator circuit and supply power toggle switch. Two heating members are located outside working chamber, the third heating member is arranged under chamber bottom. Body and door are formed of metal. Door is arranged in body wall and has insert made of heat-resistant plastic having black color. Working chamber comprises transparent door and detachable shelves formed as netted trays of corrosion-resistant material. Body wall and chamber wall have magnetic locks. EFFECT: simplified structure, increased reliability and usability. 4 cl, 2 dwg

Description

The invention relates to medical thermostats and is intended for the storage of biological substances that require maintaining thermal conditions within strictly specified limits, in particular in medicine and sanitation for bacteriological, microbiological, bacteriological, virological and biochemical studies.

Known thermostat described in RF patent No. 2076350 “Thermostat” according to cl. G 05 D 23/30, B 01 L 7/00, claimed 07/19/95, publ. 03/27/97.

The well-known thermostat contains a thermally insulated housing with a working chamber placed in it with the formation of air channels between them, a cooling unit located in the air stream leaving the working chamber, a power supply, to the outputs of which are connected the inputs of electrical units in the form of a fan, whose impellers are placed in channels, and the first control unit, the outputs of which are connected to the heater, and the first setpoint and the first temperature sensor located in the air stream are connected to the control inputs entering the working chamber after the heater, a second temperature sensor, and the inputs of the cooling unit and the power supply connected to the bus power supply, is additionally equipped with cold elements and an electric battery, while the cold elements are placed in the air channels between the cooling unit and the heater, the power supply is made in the form a rectifier connected to the outputs with the same poles of the electric battery and to the inputs of the electrical units, while the cold elements are made with the possibility of tripping temperature at a temperature lower than the starting temperature.

The well-known thermostat maintains a predetermined temperature regime both at elevated and at low ambient temperatures, however, the disadvantage of the known thermostat is the complexity of its design. Known thermostat for the storage of biological material described in the patent of the Russian Federation No. 2049344 according to class. G 05 D 23/39, “Low-temperature thermostat for storing thermolabile biological material”, decl. 06/29/93, publ. 11/27/95.

Known thermostat is used for long-term storage of biological material, in particular blood plasma. It contains a thermally insulated working chamber having a cooling unit and divided by shelves for placing containers with biological material into compartments, containers with heat-accumulating substance in each compartment on the side walls of the chamber, temperature sensors according to the number of chamber compartments, the outputs of which are connected to the information inputs of the emergency emergency block and a temperature meter through a multi-channel switch; the power supply bus of the thermostat's electrical components is connected to the battery output and the output of the stationary power supply, and the control input of the threshold alarm unit is connected to the output of the stationary power supply.

Its disadvantage is the complexity of the design.

Closest to the technical nature of the claimed is a thermostat for storing biological substances, described in RF patent No. 2054608 “Portable thermostat for transporting and storing biological substances” according to cl. F 25 D 3/14, claimed 02.17.93, publ. 02/20/96 and selected as a prototype.

The well-known thermostat contains a thermally insulated plastic case with a lid, inside which there is a working chamber made of corrosion-resistant metal, a Peltier thermoelectric module, the heating element of which, a radiator and a fan are located under the bottom of the working chamber. A foam insulation is installed between the case and the camera. The top of the thermostat has a cover with a hatch, equipped with a gramophone type lock; on its body there is a connector for supplying voltage and a control panel with a toggle-switch for switching on the power voltage, an automation unit, a fuse for protecting the automation unit and LEDs for monitoring the protection of the thermostat. The automation unit contains a temperature sensor mounted on the camera, and a temperature sensor included in the measuring bridge mounted on a thermal battery, a measuring bridge, an amplifier and a comparison circuit connected in series, as well as a pulse-width modulator, a direct current generator, and a control thermistor block. In the upper part of the thermostat housing mounted handles for transferring the thermostat, made rotary relative to horizontal hinges. The thermostat housing also has ventilation windows closed with grilles to prevent foreign objects from entering the air channel of the thermostat, and supports are attached to the lower part of the body to fix the thermostat in the vehicle on the supporting platform.

The disadvantage of the thermostat is the complexity of its design, due to the presence of a radiator and a fan, as well as the complexity of the automation unit for temperature control, protection and indication. In addition, the implementation of the housing made of plastic does not provide sufficient structural strength, and the presence of one heating element made on the Peltier effect and placed under the bottom requires a complex temperature control system for stable and accurate maintenance of a given temperature regime. The execution of the cover (door) in the upper part of the housing is not very convenient during operation, as well as the absence of shelves inside the working chamber. Moreover, the presence of a fan requires additional energy consumption, as well as the use of only one heating element for heating.

The aim of the invention is to simplify the design of the thermostat while increasing its reliability and ease of use, as well as reducing the power consumption of the device.

This goal is achieved by the fact that in a thermostat for storing biological substances, containing a case equipped with a door with a lock, inside which there is a working chamber made of corrosion-resistant material, separated from the case by a layer of heat-insulating material, a thermoelectric module for heating the working chamber, the heating element of which is placed under the bottom of the chamber in the air gap between it and the layer of heat-insulating material, a control unit including temperature sensors, a temperature dial, indicators, a power supply blister, a DC generator, an amplifier and a comparison circuit, according to the invention, the case and the door are made of metal, the door being located in the side wall of the case and having an insert of heat-resistant black plastic inside, the working chamber is equipped with a door made of transparent material and removable shelves in the form of mesh pallets made of corrosion-resistant metal, while the door of the case and the door of the working chamber are equipped with magnetic locks, the thermoelectric module is made in the form of three distributed electric heating elements, two of which are located behind the side walls of the chamber in the air gaps between the walls of the chamber and the layer of heat-insulating material, the control unit is made in a separate housing, and temperature sensors are located behind the side walls of the working chamber.

In this case, foam insulation or heat-resistant corrugated cardboard or foam insulation between the side walls of the working chamber and the housing and heat-resistant corrugated cardboard between their rear walls can be used as heat-insulating material.

The execution of the body and its doors of metal increases the mechanical reliability of the structure; the presence of a transparent door in the working chamber provides ease of use, allowing you to control the position of containers with biological substances in the chamber, and at the same time eliminates the possibility of a sharp decrease in temperature when the thermostat case doors are opened; the presence of removable shelves in the chamber and magnetic locks in its door and the door of the housing provides ease of use. The implementation of the thermoelectric module in the form of three distributed heaters located under the bottom and behind the side walls of the chamber provides uniform heating of the working chamber and stable maintenance of the thermal regime with a fairly simple design of the thermostat; This is also facilitated by the presence of an internal black insert on the inside of the door of the housing, and the placement of temperature sensors of the control unit behind the side walls of the camera eliminates their damage when disinfecting the internal walls of the camera. The use of distributed electric heaters having low energy consumption as heating elements, in combination with the presence of a door in the chamber and a door of the housing, ensuring the tightness of the thermostat, reduces energy consumption. The implementation of the control unit in a separate housing provides ease of repair and maintenance, as well as the ability to remote control.

The inventive thermostat has novelty in comparison with the prototype, differing from it in the execution of the body and the door made of metal, the presence of an internal door of transparent material and removable shelves in the chamber, the supply of the door of the body and the chamber door with magnetic locks, the presence of an inner insert made of black plastic in the door of the case, the implementation of the thermoelectric module in the form of three distributed electric heaters located behind the side walls and under the bottom of the chamber, the placement of temperature sensors behind the side walls of the chamber and Making a control unit in a separate housing providing collectively achieve the desired result.

The applicant is not aware of technical solutions possessing the mentioned distinguishing features, which together ensure the achievement of a given technical result, therefore, he considers that the claimed technical solution meets the criterion of “inventive step”.

The claimed design of the thermostat can be widely used in medicine and sanitation for bacteriological, microbiological, bacteriological, virological and biochemical studies and therefore meets the criterion of "industrial applicability".

The invention is illustrated by drawings, which represent:

figure 1 - General view of the design of the thermostat; figure 2 is an electrical diagram of a thermostat.

The thermostat for storing biological substances (figure 1) contains a metal case 1 with a door 2 made of metal, equipped with a rubber sealing case 3 with magnetic inserts forming a magnetic lock 4, and an inner insert 5 of black color. Inside the housing 1, separated from it by a thermal insulation layer 6, a working chamber 7 is made of corrosion-resistant metal, for example stainless steel, with a door 8 made of transparent heat-resistant plastic and removable shelves 9 made in the form of mesh pallets also made of stainless steel. Under the bottom of the working chamber 7 and behind its side walls there are distributed electric heaters (RES) 10 of the thermoelectric module made of plates made of heating cloth specially made for this purpose, protected by a dielectric layer with high dielectric strength. The control unit 11 (figure 2) includes series-connected temperature sensors 12 located behind the side walls of the working chamber 7 of the thermostat, an amplifier 13, a comparison circuit 14 and REN 10 (in the thermostat), as well as a series-connected current generator 15 and a reference temperature adjuster 16 the output of which is connected to the second input of the comparison circuit 14. The third input of the circuit 14 and the input of the generator 15 are connected to the output of the power source 17, which is connected to the power supply via the toggle switch 18. There is a temperature indicator 19. Block 11 is made in a separate housing. It can be mounted on top of the thermostat housing or located at some distance from it. Sensors 12 are placed behind the side walls of the chamber 7 to prevent their damage during disinfection of the working chamber. As a heat insulator 6 can be used, in particular, penoizol or heat-resistant corrugated cardboard. A combined heat insulator - a foam insulator between the side walls of the housing and the chamber and a heat-resistant corrugated cardboard between their rear walls can be used.

The thermostat operates as follows.

Open the door 2 in the thermostat housing 1, then the door 8 of the chamber 7, install the biological substances to be studied on the shelves 9 of the chamber 7 in Petri dishes, flasks or retorts, successively close the door 8 of the chamber 7, then the door 2 of the housing 1.

The power source 17 is connected to the network using the toggle switch 18. Then the current generator 15 is turned on and using the reference temperature setter 16, made in the form of a potentiometer, the required stabilization temperature is set, controlled by the indicator 19. In this case, the temperature in the thermostat chamber 7 must exceed the temperature environment more than 5 ° C. The heaters 10 of the thermoelectric module are heated until they reach the set temperature - a stable temperature regime is reached within four hours. When the set temperature is reached, the signal from the sensors 12 passes to the amplifier 13 and then to the comparison circuit 14, which also receives the signal from the temperature setter 16: when the temperatures are equal, the supply voltage does not come in and the heater does not turn on. If the temperature at the sensor 12 is lower than the temperature at the setter 16, then the heaters 10 turn on and the temperature rises in the working chamber 7. Biological substances are in the thermostat for the set time, then the thermostat is turned off in the reverse order and removed from the thermostat.

Compared with the prototype of the inventive thermostat is simpler in design with good reliability, more convenient to use and consumes less electricity.

Claims (4)

1. The thermostat for storing biological substances, comprising a housing equipped with a door with a lock, inside which there is a working chamber made of corrosion-resistant material, separated from the housing by a layer of heat-insulating material, a thermoelectric module for heating the working chamber, the heating element of which is placed under the bottom of the chamber in the air gap between it and a layer of heat-insulating material, a control unit including temperature sensors, a temperature setter, a direct current generator, an amplifier, a comparison circuit , indicators, toggle switch for supply voltage, characterized in that the case and the door are made of metal, the door is located in the side wall of the case and has an inset of heat-resistant black plastic inside, the working chamber is equipped with a door made of transparent material and removable shelves in the form mesh pallets made of corrosion-resistant metal, while the door of the case and the chamber door are equipped with magnetic locks, the thermoelectric module is made in the form of three distributed electrical heating elements, two and of which are located behind the side walls of the chamber, the control unit is made in a separate housing, and temperature sensors are located behind the side walls of the working chamber. 2. The thermostat for storing biological substances according to claim 1, characterized in that penoizol is used as the heat-insulating material. 3. The thermostat for storing biological substances according to claim 1, characterized in that a heat-resistant corrugated cardboard is used as a heat-insulating material. 4. The thermostat for storing biological substances according to claim 1, characterized in that foam insulation is used as heat-insulating material between the side walls of the working chamber and the housing, and a heat-resistant corrugated cardboard between their rear walls.

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