DE102007057651A1 - Temperature control system for cyclic heating up and cooling of e.g. chemical sample, has blocks heated up and/or cooled by tempering mechanisms e.g. electrically heating and cooling elements, that are in close thermal contact with blocks - Google Patents

Abstract

The system (1) has warm-conductive blocks (2, 2') heated up and/or cooled by tempering mechanisms (3, 3') e.g. electrically heating and cooling elements such as peltier elements, that are in close thermal contact with the blocks. The tempering mechanisms are flowed-through by heat-carrying liquids. One of the blocks is arranged between the neighboring tempering mechanisms, and a heat transfer unit is arranged at a distance at sides of the block. The tempering mechanisms are controlled and regulated by a control equipment. An independent claim is also included for a method for cyclic tempering of samples in blocks from a warm-conductive material in a temperature control system.

Description

The The present invention relates to a tempering system of biological, medical and chemical samples, in particular with equipment used for duplication of DNA structures be used.

Such methods and systems are known from US 2007/0113880 A1 . EP 1 356 303 . EP 1 135 211 . EP 1 090 141 and DE 202 21 055 known.

These so-called PCR apparatuses are used in microbiology for DNA analysis used. Depending on which will be 48 or 96 sample pots with chemicals / enzymes in matching holes of a postcard-sized Inserted metal plate and heats it from 50 to 90 ° C. and back - about 100 times high and back. In order for these cycles not to take too much time, there are big ones Heating and cooling required, what often Peltier elements are installed. That has the elegance of being with one Current reversal can switch from heating to cooling.

The have known in the prior art devices and methods generally a heated plate on which a variety of Have holes for receiving sample containers. The Heat and cold supply to the metal plate takes place on the ground via the thermally coupled Peltier elements. The opposite thermal power will be on the other Peltier side supplied to the environment via aluminum profiles.

The Holes are arrayed in rows and rows and carry all approximately the same temperature as the immediate one Environment of the heated plate. To the heatable plate with her Holes is thermal a heating or cooling element, in usually a Peltier element, thermally coupled, by one Control unit is driven to the required different Driving time-dependent temperature cycles. Below the Peltier elements are cooling fins or others Facilities arranged to dissipate the heat loss and serve the opposite thermal performance.

When disadvantageous in these systems, it is felt that the necessary Temperature differences for cyclic heating and cooling of the Samples carried out solely with the help of the cooling equipment so that a relatively high power dissipation of energy too is recorded. Another disadvantage is the known Systems further that these systems are thermally proportionate are sluggish and thereby the total time to pass through Cycles is unnecessarily prolonged.

Therefore It is an object of the present invention to provide a system according to a predetermined method to provide, which in capable of reducing the thermal ballast and thus the cycle times as well as reduce manufacturing costs.

These Task is with the characterizing features of the main claims solved.

The Tempering system according to the invention for fast cyclic heating and cooling of samples with at least one thermally conductive block, by means of heated and / or suitable temperature control devices is cooled, is characterized by at least two Blocks with at least one temperature control, the with the blocks in close thermal contact. By Pressing further temperature control unit / block pairs can Block arrays are formed in which the blocks alternate are warm and cold.

The inventive method for cyclic temperature control of samples in blocks of thermally conductive Material in a tempering system is characterized in that at least two blocks of thermally conductive Material are combined to form a tempering, wherein the at least two blocks in close thermal contact be brought with at least one tempering unit and of a adjustable control unit to different temperatures (T) to same time (t) be brought.

one The basic idea of this invention is that the counter set thermal power is not dissipated, but to leave these in the metal plate. Arrange between stripes the metal plate with the holes for the vessels Peltier elements, so with a suitable arrangement and interconnection the strips alternately heated and cooled. The Stripes are therefore alternately warm and cold and vice versa. In this thermal swinging ("thermal swing") remains the total temperature the apparatus almost unchanged, apart from the power loss the Peltier elements. There are thus no opposite benefits dissipated, what faster cycles, a smaller design, and energy savings. The power loss from Z. B. Peltier elements serves to raise the overall temperature the system above room temperature.

advantageous Training can be found in the dependent claims.

It is advantageous that the temperature control are electrical heating and cooling elements, for. B. Peltier elements and individually controlled who the.

Farther it is advantageous that the tempering of a control device is controlled and regulated.

Advantageous it is further that the control device is programmable.

Advantageous it is also that the blocks to be tempered elongated are formed.

Advantageous it is further that the blocks at least one recess exhibit.

One Another advantage is that the blocks to be tempered are plate-like and elongated and at the after top-facing surface recesses for receiving samples exhibit.

Advantageous It is further that the heat generated within a heat-insulating shell conserved and stored is and the dissipated power loss of tempering to increase and maintain the heat content of the Overall system is used.

Advantageous It is also that the temperature cycles in both the time (t) and also in the temperature (T) are variably controlled.

Advantageous it is further that the temperature cycles preprogrammed from t1 to t2 and automatically run cyclically.

Advantageous It is in certain applications that the temperature cycles (t1 to t2) are identical.

Further Features essential to the invention are the subclaims refer to.

in the Now, the invention will be described in more detail with reference to drawings described in more detail. It shows

1 : a schematic representation of the tempering system ( 1 ) in cross section in front view;

2 : a schematic representation of the tempering system ( 1 ) in plan view;

3 : a schematic temperature-time diagram of a block ( 2 ) with a stepped temperature profile;

4 : a qualitative temperature-time diagram of two juxtaposed blocks ( 2 . 2 ' ) with two curves representing a time cycle between t1 and t2.

The 1 shows a schematic front view of the tempering system according to the invention 1 , The blocks to be tempered 2 . 2 ' , which consist essentially of elongated thermally conductive material, are arranged parallel to each other. Every single block 2 . 2 ' indicates the upper facing surface 8th a plurality of, but at least one, recess 7 which can take different forms. In the recess 7 becomes the sample to be tempered 5 directly or with a special use 11 , brought in. Between the blocks 2 . 2 ' are tempering devices 3 . 3 ' arranged with a suitable thin transmission medium 4 that between the tempering device 3 . 3 ' and the blocks 2 . 2 ' is arranged at a distance (d) and thus in close thermal contact with the blocks 2 . 2 ' stand. The tempering devices 3 . 3 ' are facilities with which the blocks 2 . 2 ' be brought to a predetermined temperature (T). Frequently, so-called Peltier elements are used for this purpose, which are fed with direct current and generate heat in a current direction and generate heat when the current direction is reversed. This means that the Peltier element gets hot on one side when the current flows through and gets cold on the other side. This results in reciprocal heating and cooling of the adjacent blocks 2 . 2 ' a thermal swing. The same effect can be achieved, for example, if every second block is tempered in a predetermined cycle. The lateral arrangement of the individual basically identical blocks with the tempering 3 . 3 ' is repeatable as often as desired and depends on the requirements of the experiment to be carried out with this apparatus. Between the neighboring blocks 2 . 2 ' a temperature control is arranged at a certain distance, the sides of which are alternately hot and cold depending on the flow of current and the resulting temperatures on the adjacent blocks 2 . 2 ' be transmitted. As a result, a large part of energy, apart from power losses, is retained in the overall system, the heat flow oscillates back and forth and the opposite power must not be dissipated. This allows the two blocks 2 . 2 ' be operated at completely different temperatures at the same time. The heat that occurs when cooling a heated tempering unit 3 . 3 ' must be removed, is used reciprocally, the newly aufheizende adjacent temperature control unit 3 , or preheat the block, whereby about 1/3 of energy can be saved and the total cycle time (tges) can be shortened to half the usual heating or ramp time. The temperature profile over the entire temperature control system 1 in the transverse direction to the longitudinal axes of the individual blocks 2 . 2 ' therefore essentially not constant, but undulating, with maxima and minima of the temperatures alternating in time. In this thermal swing, the overall temperature of the apparatus remains largely unchanged. No opposite performance is dissipated, allowing for faster cycles, smaller design and energy savings. The power loss serves to raise the overall temperature of the system above room temperature. The entire temperature control system 1 is from a shell 9 surrounded for thermal separation.

The 2 shows a schematic plan view of the tempering 1 with the control device 6 , Every heatable block 2 . 2 ' has a number of recesses 7 on the upward facing surface 8th whose number depends on the type of experiment to be performed. For example, if 96 samples are needed, each block has 12 Recesses, with 12 blocks are arranged side by side. The function of the Peltier elements 3 . 3 ' in the present system has already been described above. The temperature (T) is recorded by corresponding temperature sensors, not shown here, and for control purposes of the control unit 6 fed. Instead of the Peltier elements, other tempering units can also be used 3 . 3 ' be used, for. B. hollow body, which are alternately flooded by a liquid of predetermined temperature (T) and this temperature to the blocks 2 . 2 ' submit.

The 3 shows a schematic temperature-time diagram for a block 2 with a cyclically stepped pre-programmed temperature (T). The individual temperature levels of each stage between t1 and t2 can be controlled by a control unit 6 depending on the experiment, arbitrarily set or pre-programmed.

The 4 shows two temperature curves of two adjacent blocks 2 . 2 ' that qualitatively the temporal course of the temperature cycles of the blocks 2 . 2 ' between the time t1 and t2. The individual temperature levels can with the control device 6 preprogrammed automatically pass through. The fully drawn curve (I) qualitatively shows the time course of the temperature (T) of a block 2 on the surface again, which is comparable to the temperature of a Peltier side 10 from the heated state to the cooled state as a function of time (t). The dashed curve (II) shows the reverse temperature profile of the surface of the adjacent block 2 ' or the other Peltier page 10 ' of the same Peletier element. The generated stored heat of the first block 2 becomes practically in a certain time interval (t2 - t1) on the neighboring block 2 ' transferred, whereby a certain Aufheizleistung is saved.

Similar and other embodiments of the above-mentioned. inventive concept are also included within the scope of the invention, e.g. For example instead of a Peltier element two cavities arranged that are alternately on and off or each one second block alternately with the help of electric heating up and is heated.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• US 2007/0113880 A1 [0002]
• EP 1356303 [0002]
• - EP 1135211 [0002]
• - EP 1090141 [0002]
• - DE 20221055 [0002]

Claims (16)

Tempering system ( 1 ) for cyclically heating and cooling samples with a thermally conductive block ( 2 ) by means of suitable temperature control devices ( 3 ) is heated and / or cooled, characterized by at least two blocks ( 2 . 2 ' ) with at least one tempering device ( 3 ), with the blocks ( 2 . 2 ' ) is in close thermal contact. Tempering system ( 1 ) according to claim 1, characterized in that the tempering device ( 3 . 3 ' ) electrical heating and cooling elements are, for. B. Peltier elements. Tempering system ( 1 ) according to claim 1, characterized in that the tempering device ( 3 . 3 ' ) are flowed through by heat-carrying liquids. Tempering system ( 1 ) according to claim 1, characterized in that between the adjacent temperature control devices ( 3 . 3 ' ) a block ( 2 ) and at the distance (d) on the sides of the block ( 2 ) a suitable heat transfer medium is arranged. Tempering system ( 1 ) according to one of the preceding claims, characterized in that the tempering device ( 3 . 3 ' ) from a control device ( 6 ) is controlled and regulated. Tempering system ( 1 ) according to claim 6, characterized in that the control device ( 6 ) is programmable. Tempering system ( 1 ) according to claim 1, characterized in that the blocks ( 2 . 2 ' ) are elongated. Tempering system ( 1 ) according to claim 1, characterized in that the blocks ( 2 . 2 ' ) at least one recess ( 7 ) exhibit. Tempering system ( 1 ) according to claim 1, characterized in that the blocks to be tempered ( 2 . 2 ' ) are plate-like and oblong and formed on the upwardly facing surface ( 8th ) Recesses ( 7 ) for taking samples ( 5 ) exhibit. Tempering system ( 1 ) according to one of the preceding claims, characterized by a heat-insulating casing ( 9 ), which generates the heat generated inside the envelope ( 9 ) preserves and stores. Method for the cyclic tempering of samples ( 5 ) in blocks of thermally conductive material in a tempering system ( 1 ), characterized in that at least two blocks ( 2 . 2 ' ) which are thermally in close contact with at least one tempering unit ( 3 . 3 ' ) are arranged parallel to each other and by a control unit ( 6 ) are brought to different temperatures (T) at the same time (t). Method according to claim 11, characterized in that as temperature control unit ( 3 . 3 ' ) at least two Peltier elements are used. A method according to claim 11, characterized in that the dissipated power loss of the temperature control devices ( 3 . 3 ' ) is used to increase and maintain the heat content of the overall system. Method according to claim 13, characterized in that that the temperature cycles both in time and in temperature (T) are variably controlled. Method according to claim 13, characterized in that that the temperature cycles (t1 to t2) are preprogrammed and automatically run cyclically. Method according to one of the preceding claims, characterized in that the temperature cycles (t1 to t2) identical are.