SU1270656A1 - Device for optical analyzing of biological substances - Google Patents

Abstract

The invention relates to laboratory devices for analyzing substances and materials by optical methods. The purpose of the invention is to accelerate research by reducing the time of thermal stabilization of the test substance. The device contains a heat exchanger-cuvette holder 1, a nest 4 with a measuring cuvette 5, a terminal 7 in the cap 8, a thermostating unit 9, sealing elements 10 of the cavity of the socket and an annular seal 11 of the window 3. There is an additional heat exchanger in the cavity of the cuvette 5, which has connections 13 and 14 , fixed in the lid 8 of the cuvette 5. The heat exchanger 1 has nozzles 15 and 16 through which it is connected by tubes with a thermostating unit 9 and an additional heat exchanger. The arrows indicate the direction of circulation of the thermostatic fluid. 3 il.

Description

The invention relates to laboratory devices for analyzing substances and materials by optical methods. The purpose of the invention is to accelerate research by reducing the time of thermal stabilization of the test substance. Figure 1 shows schematically a device for optical examination of biological substances; in Fig.2, section A-A in Fig.1, (section of heat exchanger-cuvette holder with a cuvette and an additional U-shaped heat exchanger installed in it); Fig. 3 is a section B-B in Fig. 3 (Sechenche cells in a plane perpendicular to the direction of the beam of the monochromator). The device contains a heat exchange ™ nick-cuvette holder 1 with lining 2 and windows 3 installed therein for the propagation of ultraviolet radiation (shown by an arrow in figure 2), nests 4 with a measuring cuvette 5 installed in it, temperature sensor 6 fixed by its output 7 the cover 8 of the cuvette 5, the thermostatting unit 9 with the temperature setter and the pump (not shown). The device also contains i-shaped sealing elements 10 of the cavity of the socket and annular seals 11 of the windows 3. In the cavity of the cuvette 5 (Figures 2 and 3) an additional heat exchanger 12 is installed, made of a glass tube bent along the U-shaped profile in two planes x. The heat exchanger 12 has nozzles 13 and 14, which are secured in the lid 8 of the cuvette 5. The TV-holder 1 has nozzles 15 and 16, through to: it is connected to the thermostating unit 9 and the additional heat exchanger 12. The arrows in FIG. show the direction of circulation of the thermostatic fluid. Figure 2 shows the interlayers of water 17 and silicone oil 18, as well as a solution 19 of the test substance in the cuvette 5. The heat exchanger-cuvette holder 1 can be made on several cuvettes 5. Measurements using the proposed device are carried out in the following way. 1 6 The solution 9 of the test substance is poured into the cuvette 5 and closed with a cap 8. At the same time, an additional heat exchanger 12 and sensor 6 are introduced into the cavity of the cuvette 5. As a result of the displacement of the solution by the heat exchanger 12, the solution level 19 increases, blocking the upper edge of the window 3, 6 is immersed in the solution 19. In the nest 4, 0.3-0.4 MP of water and OJ05-0.08 ml of silicone oil are sequentially poured. In this case, the liquid level in the nest 4 does not exceed the lower edge of the seal 11 of the window 3. The cuvette 5 is installed in the nest 4 when it touches the bottom in the nest, it is displaced by a fluid in the space bounded by the walls of the nest 4 and the cuvette 5 and seals 10 and 11, В As a result, a layer of water 17 and a layer of silicone oil 18 covering it are formed in this space. The temperature setting unit of the thermostating unit 9 establishes the initial and final temperatures, the interval of its increase and switches on the pump of the unit 9. At the same time, the circuit 9 unit 9 is the heat exchanger 12 - and 14 is the nozzle. 16 - heat exchanger - cuvette holder 1 - nozzle 15 - block 9 water starts to circulate, heated to a predetermined temperature. As temperature equilibrium is reached and the solution temperature is set, based on the data taken from sensor 6, the required parameters are recorded. Then, the temperature is increased by a predetermined interval and, after reaching a predetermined temperature of the solution, the absorption of ultraviolet radiation is recorded. The presence of absorbing elements of the cavity of the socket 4 and the window seals 1I makes it possible to create a layer of fluid between the walls of the socket 4 and the walls of the cuvette 5, which is achieved by pouring liquid into the nest 4 of the heat exchanger cuvette 1 and installing the cuvette 5 in it. the contact of the cuvette 3 with the heat exchanger-cooler holder 1, and from five sides. As a result, the process of achieving the required temperature5 is significantly increasing in the cuvette.

3 I In addition, the use of an additional U-shaped heat exchanger 12 in the cavity of the cuvette 5 makes it possible to further accelerate the achievement of the temperature equilibrium of the solution, and therefore speed up the measurement process.

Claims (1)

Invention Formula and Device for optical research of biological substances, containing a heat exchanger-cuvette holder, measuring cuvette, thermostat block - / 1 2706564 The test and temperature sensor of the studied biological substance, which differs from the fact that, in order to accelerate research by reducing the time of thermal stabilization of the test substance, an additional U-shaped heat exchanger hydraulically connected to the thermostatting unit is located in the cavity, The cuvette holder is filled with liquid and is provided with elastic webs. S (ffue.S