KR20130124801A - Temperature maintenance apparatus for tube rack - Google Patents

Abstract

The present invention relates to a temperature control device for a tube rack, more specifically, to a temperature control device for a tube rack, which maintains the temperature of a laboratory tube rack for a predetermined period of time without using separate power. The present invention comprises a body which is formed in the shape of a container with an opened top, a heating member which is accommodated in the body and heats or cools air, and a heat conduction plate which is made of high conductive material, covers the top of the body, and mounts the laboratory tube rack on the upper surface thereof.

Description

Temperature maintenance apparatus for tube racks {Temperature maintenance apparatus for tube rack}

The present invention relates to a tube rack temperature holding device, and more particularly to a tube rack temperature holding device to maintain the temperature of the tube rack (Tube Rack) for a certain time without using a separate power.

In general, an experimental tube rack has a function of maintaining a constant temperature by inserting a tube therein by forming a plurality of tube insertion holes in rows and columns on a top surface of the body composed of a thermal conductor such as aluminum.

In order to heat or cool the experimental tube rack to heat or cool the tube inserted into the tube insertion hole, the experimental tube rack is directly put in a warmer or a refrigerator and heated or cooled to a predetermined temperature.

Then, the tube is taken out of the refrigerator or the refrigerator by inserting the tube into the tube insertion hole to have a certain temperature.

However, in order to heat or cool the laboratory tube rack, a heater and a refrigerator must be provided. Therefore, the space for using the laboratory tube rack is restricted, and the heat is removed from the heater or the refrigerator by contact with the atmosphere from the moment of use. It will be taken away and will not be able to heat the tube for a long time.

In order to heat the tube for a long time, the tube inserted into the tube insertion hole needs to be replaced with a new experimental tube rack. Therefore, the temperature change of the tube may occur, thereby reducing the reliability of the experiment. This follows.

In addition, there is no way for the experimenter to quickly and accurately determine the temperature change of the experimental tube rack, and this also causes a temperature change of the tube, so the accurate experiment is often not made.

In order to solve the above problems, the present invention accommodates a heating material that generates heat or cold heat therein, and provided with a conductive plate with a high thermal conductivity on the upper side to put a test tube rack on the conductive plate to apply heat. The object is to provide a temperature holding device for a tube rack.

Tube rack temperature holding device of the present invention for achieving the above object,

A body having an open shape at the top;

A heat generating material which is accommodated in the body and generates heat or cold heat;

It is made of a high thermal conductivity material, covering the upper portion of the body, the heat conduction plate is seated on the upper surface of the experimental tube rack; characterized in that consisting of.

In addition, the body,

A temperature sensor for sensing a temperature of the heating material;

ID storage unit for storing a unique ID;

A processor for outputting an alarm signal when a difference value between a temperature value periodically detected from the temperature sensor and a set temperature value is outside a prescribed value, and reading and outputting an ID stored in the ID storage unit;

An alarm unit for generating a visual and audio alarm by the output of the processor;

A wireless transmitter for wirelessly transmitting the output of the processor to a remote site;

It includes a circuit unit consisting of; a battery for supplying power.

The present invention having such a configuration is excellent in mobility because it does not use a power source such as a separate warmer or a refrigerator, and there is no limitation of space, and also it is possible to maintain a constant temperature for a predetermined time by the built-in heating material, so the reliability of the experiment Is improved, and the temperature change of the tube rack can be confirmed accurately, so that the experiment can be carried out at a constant temperature.

1 is an exploded view of the present invention.
2 is a cross-sectional view of the combination of FIG.
3 is a circuit diagram of an alarm unit.

The present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded view of the present invention, which is composed of a body 100, a heat generating material 150, and a heat conduction plate 160.

The body 100 is an enclosure having an open top, and forms a receiving space 110, and a stepped part 120 is formed along an inner circumference at an upper side of the inner side.

In addition, the upper surface of the stepped portion 120 has a structure in which the pin coupling holes 130 are formed, respectively.

The body 100 may be made of an aluminum material having excellent thermal conductivity or may be formed of a heat insulating material having a low thermal conductivity.

The inner receiving space 110 of the body 100 is housed with a heating material 150 for generating heat or cold heat, the heating material 150 is a form that can be separated from the body 100 in the form of exchangeable It is desirable to be.

The heat conduction plate 160 is covered from the upper side of the body 100 so as to be placed on the upper end of the stepped part 120 to seal the receiving space 110. The pin insertion hole 161 is formed at a position corresponding to the pin coupling hole 130.

The heat conduction plate 160 is excellent in thermal conductivity and is made of a metal material such as aluminum, stainless steel, copper plate, etc., and is placed on the stepped portion 120 to cover and cover all the upper portions of the receiving space 110. The pin 162 inserted into the 161 and the pin coupling hole 130 to couple the heat conducting plate 160 and the body 100 is preferably in the form of a pin that can be coupled and separated in a bolt or one-touch form.

In the case of the tube rack 200 as a general form, a plurality of tube insertion holes 210 are formed in a row and a column so that the tube 220 is inserted therein, and is formed of aluminum having excellent thermal conductivity.

FIG. 2 is a cross sectional view of FIG. 1, in which a heat generating material 150 is inserted into the receiving space 110, and a heat conducting plate 160 is covered on the upper side of the body 100 to the fin 162. By a fixed form.

At this time, the tube rack 200 is mounted on the upper surface of the heat conduction plate 160 so that the bottom surface is in contact with the upper surface of the heat conduction plate 160 to heat or cool heat generated from the heat generating material 150 is the heat conduction plate 160. By passing through the tube rack 200 to maintain a constant temperature.

In addition, the upper portion of the body 100 is formed higher than the stepped portion 120, to prevent the tube rack 200 is separated in the lateral direction.

When the body 100 is made of a material having excellent thermal conductivity, the body 100 in a state in which the heating material 150 and the heat conduction plate 160 are combined is immediately put in a warmer or a refrigerator, heated or cooled, and then taken out of the heat conduction plate ( The tube rack 200 is placed on an upper surface of the 160 to apply heat.

On the contrary, when the heat insulating material is made of a material having low thermal conductivity, the heating material 150 is put in a warmer or a refrigerator beforehand to be heated or cooled, and then taken out and put in the receiving space 110 of the body 100 to cover the heat conducting plate 160. As a result, it can be used immediately at the test site.

This structure has the advantage of excellent mobility by allowing the heating material 150 to be heated or cooled in advance to insulate and then move to an experimental place to be accommodated in the body 100 immediately before the experiment.

In order to accommodate the heat generating material 150, the separation and coupling of the heat conduction plate 160 should be easy. For this purpose, the fin 162 and the pin coupling hole 130 are preferably one-touch structure and can be separated.

On the other hand, since the heat generating material 150 is accommodated in the interior of the body 100, it is very difficult for the experimenter to easily check the change in temperature.

When the temperature change occurs, the experiment with reliability cannot be made, so the temperature change of the heating material 150 should be immediately informed to the experimenter.

To this end, a circuit unit 300 is installed at the bottom of the accommodation space 110. The circuit unit 300 periodically detects the temperature of the heat generating material 150 by the temperature sensor 310 as shown in FIG. In operation 320, the processor 320 compares the set temperature value with the sensed input value.

When the comparison result is out of the prescribed value, that is, when the temperature change is large and affects the experiment, the processor 320 outputs an alarm signal through the alarm unit 350 to alert the experimenter to the alarm sound and the visual alarm signal. (For example, blinking red LED).

At the same time, the processor 320 reads the ID stored in the ID storage unit 330 and wirelessly transmits the ID stored in the ID control unit 340 to a remote control panel through the wireless transmitter 340 to check the temperature change of the plurality of temperature maintaining apparatuses and to respond to such an alarm. Immediate notification to the laboratory's experimenter ensures immediate recognition.

100: body 110: receiving space
120: step portion 130: pin coupling hole
150: heat generating material 160: heat conduction plate
161: pin insertion hole 162: pin
200: tube rack 300: circuit part

Claims (3)

A body having an open shape at the top;
A heat generating material which is accommodated in the body and generates heat or cold heat;
A thermal conductivity plate made of a material having high thermal conductivity, covering the upper portion of the body, the thermal conductive plate is seated on the upper surface of the experimental tube rack.
The temperature maintaining apparatus for a tube rack according to claim 1, wherein the body is formed of a material having high thermal conductivity or a heat insulating material having a low thermal conductivity.
According to claim 1, wherein the body
A temperature sensor for sensing a temperature of the heating material;
ID storage unit for storing a unique ID;
A processor for outputting an alarm signal when a difference value between a temperature value periodically detected from the temperature sensor and a set temperature value is outside a prescribed value, and reading and outputting an ID stored in the ID storage unit;
An alarm unit for generating a visual and audio alarm by the output of the processor;
A wireless transmitter for wirelessly transmitting the output of the processor to a remote site;
Tube holding temperature holding device comprising a circuit portion consisting of; a battery for supplying power.

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