KR20100011062A - Electromagnetic interference-free fluid-thermostat - Google Patents

Abstract

PURPOSE: A fluid thermostat without electro-magnetic interference is provided to exclude the electro-magnetic interference by separating a power part and a temperature control part generating an electromagnetic field with a chamber part. CONSTITUTION: A fluid thermostat without electro-magnetic interference comprises the following: a chamber part(10) with a temperature sensor measuring temperature of fluid and discharging the fluid; a fluid circulation connection pipe(20) connected to a chamber part and circulating the fluid; a temperature adjusting part(30) controlling a thermostat state of the fluid; a power part(50) supplying power to the temperature adjusting part; and a control part(40) controlling the temperature adjusting part and the power part.

Description

Electromagnetic Interference-Free fluid-Thermostat

The present invention relates to a fluid thermostat that maintains a constant temperature, and separates electromagnetic field generating elements such as a heater / peltier element, a fluid circulation fan, and a power supply device from the chamber part and separates them from the chamber part. It relates to a fluid thermostat with no electromagnetic interference so that the interference caused by the interference is excluded.

Various precision tests or experiments are affected by temperature, so that the temperature is kept constant at all times, that is, to be performed in a thermostat with little change in temperature. Such a thermostat is generally a device such as a heater used to maintain a temperature or a Peltier element used to cool, a circulation fan for uniformly distributing the heat generated therein, and a temperature for measuring the temperature. It consists of a sensor and a power supply unit for supplying power to these components, and is controlled to maintain a constant temperature through PID control in software.

However, these components all generate electromagnetic fields during operation. Of course, in the case of the heater, the two electric wires can be wound at the same time to reduce the electromagnetic field to some extent, but in the case of the Peltier element used during cooling, a pulse type electromagnetic field is generated by instantaneously turning on / off a strong current. In addition, the circulation fan generates a magnetic field of several tens to several kHz. In the power supply unit, an electromagnetic field is generated not only in the electromagnetic field of the AC power itself but also in the control of various components. Of course, electric fields can be shielded if they are made of enclosures using metallic materials with good conductivity. However, in order to shield the magnetic field, expensive magnetic materials have to be used, and there are also difficulties in processing. Moreover, current common thermostats are integrated with these electromagnetic field sources and chambers, so strong electromagnetic fields generated by these members can cause noise in precision measurements or cause sensor malfunctions and negatively affect the accuracy of the measured values. There is a problem that gives.

The present invention is to solve the above-described problems, the object of the present invention is to separate the power supply and temperature control parts that are the components that generate the electromagnetic field from the chamber to prevent the electromagnetic interference by measuring the malfunction of the measurement sensor or the measurement object And a fluid thermostat free of electromagnetic interference to prevent noise and maintain a constant temperature.

The fluid thermostat without electromagnetic interference of the present invention includes a chamber unit 10 having temperature sensors 14, 17a, and 17b for measuring the temperature of the fluid into and out of the fluid; A fluid circulation connecting pipe 20 connected to the chamber part 10 to allow fluid circulation to the chamber part 10; The temperature control is connected to the fluid circulation connection pipe 20 and controls the temperature of the fluid flowing into and out of the chamber part 10 according to the measurement temperature of the temperature sensors 14, 17a and 17b to maintain a constant temperature state. Part 30; A power supply unit 50 for supplying power to the temperature control unit 30; And a control unit 40 for controlling the temperature control unit 30 and the power supply unit 50; It is made, including, the chamber 10 is connected to the fluid circulation connector 20 to be excluded from the interference of the electromagnetic field generated from the temperature control unit 30, the power supply unit 50 and the control unit 40. It features.

In addition, the chamber 10 includes a fluid inlet 11 through which fluid is introduced, a fluid dispersing unit 12 through which fluid is introduced and dispersed, a fluid outlet 13 through which fluid is discharged, and an internal central part. Located in the first inner chamber 15 having a temperature sensor 14 for measuring the temperature of the fluid, and the first inner chamber 15 is accommodated to receive the fluid discharged to the fluid outlet (13) And a first outer chamber 19 having a fluid discharge part 16 for discharging the received fluid and temperature sensors 17a and 17b for measuring the temperature of the discharged fluid, and the fluid circulation connector 20 ) Is connected to the fluid inlet 11 of the first inner chamber 15 to receive the fluid inlet tube 21 and the fluid inlet tube 21, the first outer chamber 19 to receive the fluid inlet tube 21 It is characterized by consisting of a fluid discharge pipe 22 to be connected to the fluid discharge portion 16 of the fluid discharge.

In addition, the temperature control unit 30 is connected to the fluid discharge pipe 22 and the second outer chamber 31 for receiving the fluid discharged to the fluid discharge pipe 22 and the second outer chamber 31 inside The fluid inlet part 32, which is accommodated in the second outer chamber 31, into which the fluid is introduced, and which is connected to the fluid inlet pipe 21 and flowed into the fluid inlet part 32, are introduced into the fluid inlet part 32. The fluid discharge part 16 to be discharged to the tube 21 and the fluid inside the fluid inlet 32 to be heated or cooled by the temperature difference measured by the temperature sensor 14 It is provided at the rear of the heating / cooling part 33 and the heating / cooling part 33 to suck the fluid into the fluid inlet part 32 and to discharge the sucked fluid to the fluid discharge part 16 to supply the fluid. It consists of a second inner chamber 35 is provided with a fluid circulation fan 34 for forced circulation It shall be.

In addition, the heating / cooling unit 33 is characterized in that the Peltier element is cooled by one side and the other side is radiated by the heater and the Peltier Effect (Peltier Effect).

In addition, two fluid outlets 13 of the first inner chamber 15 are provided adjacent to each other, and connect the first inner chamber 15 and the first outer chamber 19 between the fluid outlets 13. The partition 18 is provided to divide the first outer chamber into two compartments so that fluid flows outside the first inner chamber 15.

In addition, the chamber 10, the fluid circulation connecting pipe 20 and the outside of the temperature control unit 30 is characterized in that it is surrounded by a heat insulating material 60 for blocking the heat of the outside air.

According to the fluid thermostat without electromagnetic interference according to the present invention, the power frequency (60 Hz in Korea), harmonic wave, magnetic field of several tens to several kHz by the fluid circulation fan, pulse type electromagnetic field and heater generated in the Peltier element, respectively, By eliminating the electromagnetic fields generated by the control unit of the power supply unit to control the components of the system, it is possible to perform various precise tests or experiments in the internal environment of the thermostat, thereby greatly improving the resolution, reliability, and accuracy of the measured values. .

Hereinafter, a fluid thermostat without electromagnetic interference according to the present invention will be described with reference to the accompanying drawings.

1 is a cross-sectional view showing a fluid thermostat without electromagnetic interference according to the present invention.

As shown, the fluid thermostat without electromagnetic interference according to the present invention includes a chamber portion 10 through which fluid is introduced and discharged; A fluid circulation connector 20 connected to the chamber part 10; A temperature control unit 30 connected to the fluid circulation connection pipe 20 and controlling a temperature of a fluid flowing into and out of the chamber part 10; And a power supply unit 50 supplying power to the temperature control unit 30. A control unit 40 for controlling the temperature control unit 30 and the power supply unit 50; It is made, including.

The chamber portion 10 is provided with temperature sensors (14, 17a, 17b) for measuring the temperature of the fluid is introduced and discharged and the fluid flows in and out. The chamber unit 10 may have a double structure and may have a single structure.

In the drawings, a case in which the chamber part 10 has a double structure is illustrated, and a case in which the chamber part 10 is a single structure will be omitted.

The chamber part 10 has a dual structure including a first inner chamber 15 and a first outer chamber 19 in which the first inner chamber 15 is accommodated.

The first inner chamber 15 is located at the fluid inlet 11 through which the fluid is introduced, the fluid dispersing unit 12 for dispersing the fluid therein, the fluid outlet 13 for discharging the fluid, and the inner central part. The temperature sensor 14 for measuring the temperature of the fluid is provided.

At this time, the fluid dispersing unit 12 may have a structure such as a general shower having a plurality of fluid ejection holes for fluid dispersion, and the fluid introduced by the fluid dispersing unit 12 is the temperature of all spaces in the chamber. It is evenly distributed.

The first outer chamber 19 accommodates the fluid discharged to the fluid discharge port 13 in which the first inner chamber 15 is accommodated, the fluid discharge part 16 for discharging the received fluid, and the discharged fluid. Temperature sensors 17a and 17b are provided to measure the temperature.

The temperature on the inner space of the first inner chamber 15 is measured by the temperature sensor 14, and the measured temperature is a reference value of PID control for controlling the temperature by the temperature controller 30. In addition, the temperature sensors 17a and 17b located in the first outer chamber 19 measure the temperature of the first outer chamber 19 to monitor the temperature difference with the first inner chamber 15.

In addition, two fluid outlets 13 of the first inner chamber 15 are provided adjacent to each other, and connect the first inner chamber 15 and the first outer chamber 19 between the fluid outlets 13. Thus, the partition wall 18 may be provided to divide the first outer chamber into two compartments so that fluid flows out of the first inner chamber 15. In this case, the fluid flows to the outside of the first inner chamber 15 so that the fluid inside the first outer chamber can perform heat exchange.

The fluid circulation connecting pipe 20 is connected to the chamber portion 10 and serves to make the fluid circulation to the chamber portion 10, the chamber portion 10 inside the temperature control portion 30, It is characterized in that connected to the fluid circulation connector 20 so as to be excluded from the interference of the electromagnetic field generated from the power supply unit 50 and the control unit 40.

In this case, the fluid circulation connection pipe 20 is connected to the fluid inlet 11 of the first inner chamber 15 to receive the fluid inlet tube 21 and the fluid inlet, and receives the fluid inlet tube 21 And it is preferably made of a fluid discharge pipe 22 is connected to the fluid discharge portion 16 of the first outer chamber 19 to discharge the fluid.

The temperature control part 30 is connected to the fluid circulation connector 20 and the temperature of the fluid flowing into and out of the chamber part 10 according to the measurement temperature of the temperature sensors 14, 17a and 17b is constant temperature. It controls the temperature to maintain the state.

At this time, the temperature control is compensated by the PID control device to maintain the set temperature.

At this time, the temperature control unit 30 is connected to the fluid discharge pipe 22 and the second outer chamber 31 for receiving the fluid discharged to the fluid discharge pipe 22 and the second outer chamber 31 inside The fluid inlet part 32, which is accommodated in the second outer chamber 31, into which the fluid is introduced, and which is connected to the fluid inlet pipe 21 and flowed into the fluid inlet part 32, are introduced into the fluid inlet part 32. The fluid discharge part 16 to be discharged to the tube 21 and the fluid inside the fluid inlet 32 to be heated or cooled by the temperature difference measured by the temperature sensor 14 It is provided at the rear of the heating / cooling part 33 and the heating / cooling part 33 to suck the fluid into the fluid inlet part 32 and to discharge the sucked fluid to the fluid discharge part 16 to supply the fluid. The second inner chamber 35 is provided with a fluid circulation fan 34 for forcibly circulating the wind It is.

The heating / cooling unit 33 is preferably a Peltier element in which one side is cooled by the heater and the Peltier Effect and the other side is radiated.

As such, the temperature control part 30 has a double structure such that the heating / cooling part 33 and the fluid circulation fan 34 are accommodated in the second internal chamber 35. And it is possible to reduce the generation of the electromagnetic field by the fluid circulation fan (34).

The power supply unit 50 is installed on one side of the temperature control unit 30 and serves to supply power.

The control unit 40 controls the temperature control unit 30 and the power supply unit 50, and serves to maintain a set temperature by compensatively canceling by PID control.

In addition, the outside of the chamber 10, the fluid circulation connecting pipe 20 and the temperature control unit 30 to be surrounded by a heat insulating material 60 for blocking the heat of the external fluid to influence the influence of the external air. It is desirable to reduce.

As described above, the fluid thermostat without electromagnetic interference according to the present invention is provided with a constant temperature by providing the internal environment of the thermostat by removing the heating and cooling of the fluid, forced circulation of the fluid, PID control, and interference of the electric and magnetic fields generated by the power supply. Precision tests or experiments can be carried out, which can contribute greatly to the improvement of uncertainty as well as accuracy.

1 is a view showing the structure of a fluid thermostat without electromagnetic interference in accordance with the present invention.

<Explanation of symbols for the main parts of the drawings>

10: chamber portion 11: fluid inlet

12: fluid dispersion part 13: fluid outlet

14: temperature sensor 15: first internal chamber

16: fluid outlet 17a, 17b: temperature sensor

18: bulkhead 19: first outer chamber

20: fluid circulation connector 21: fluid inlet pipe

22: fluid discharge pipe 30: temperature control unit

31: second outer chamber 32: fluid inlet

33: heating / cooling part 34: fluid circulation fan

35: second internal chamber 40: control unit

50: power supply 60: heat insulating material

Claims (6)

A chamber unit 10 having temperature sensors 14, 17a, and 17b for introducing and discharging the fluid and for measuring the temperature of the fluid to be introduced and discharged; A fluid circulation connecting pipe 20 connected to the chamber part 10 to allow fluid circulation to the chamber part 10; The temperature control is connected to the fluid circulation connection pipe 20 and controls the temperature of the fluid flowing into and out of the chamber part 10 according to the measurement temperature of the temperature sensors 14, 17a and 17b to maintain a constant temperature state. Part 30; A power supply unit 50 for supplying power to the temperature control unit 30; And A control unit 40 for controlling the temperature control unit 30 and the power supply unit 50; It is made, including The electromagnetic field is characterized in that the interior of the chamber 10 is connected to the fluid circulation connector 20 so as to be excluded from the interference of the electromagnetic field generated from the temperature control unit 30, the power supply unit 50 and the control unit 40. Fluid bath without interference. The method of claim 1, The chamber part 10 is located on the fluid inlet 11 through which the fluid is introduced, the fluid dispersing part 12 through which the fluid is introduced and dispersed, the fluid discharge port 13 through which the fluid is discharged, and the inner central part. The first inner chamber 15 is provided with a temperature sensor 14 for measuring the temperature of the, and the first inner chamber 15 is accommodated to receive the fluid discharged to the fluid outlet 13, the received fluid A first external chamber 19 having a fluid discharge part 16 to discharge, and temperature sensors 17a and 17b for measuring the temperature of the discharged fluid, The fluid circulation connecting pipe 20 is connected to the fluid inlet 11 of the first inner chamber 15 to receive the fluid inlet pipe 21 and the fluid inlet, the fluid inlet pipe 21 and the The fluid thermostatic chamber without electromagnetic interference, characterized in that the fluid discharge pipe 22 is connected to the fluid discharge portion (16) of the first outer chamber (19) to discharge the fluid. The method of claim 2, The temperature control part 30 is connected to the fluid discharge pipe 22 and accommodated in the second outer chamber 31 and the second outer chamber 31 for receiving the fluid discharged to the fluid discharge pipe 22. And a fluid inflow portion 32 into which the fluid contained in the second outer chamber 31 flows, and a fluid inflow portion 32 connected to the fluid inflow tube 21 and flowing into the fluid inflow portion 32. The fluid discharge part 16 to be discharged to the air 21 and the fluid introduced into the fluid inlet part 32 by the temperature difference measured by the temperature sensors 15, 17a and 17b. It is provided at the rear of the heating / cooling part 33 and the heating / cooling part 33 to cool the liquid so that the fluid flows into the fluid inlet part 32 and discharges the sucked fluid to the fluid discharge part 16. And a second inner chamber 35 having a fluid circulation fan 34 for forcibly circulating the fluid. Fluid thermostat without electromagnetic interference by gong. The method of claim 3, wherein The heating / cooling part (33) is a fluid thermostatic chamber without electromagnetic interference, characterized in that the one side is cooled by the heater and the Peltier effect (Peltier Effect) is a Peltier element that radiates the other side. The method of claim 2, Two fluid discharge ports 13 of the first inner chamber 15 are adjacent to each other, The first inner chamber 15 and the first outer chamber 19 between the fluid outlet 13 are connected to each other so that the first outer chamber is divided into two compartments, and the fluid is discharged to the outside of the first inner chamber 15. A fluid thermostat free of electromagnetic interference, characterized in that the partition 18 is provided to flow. The method according to any one of claims 1 to 5, Fluid chamber without electromagnetic interference, characterized in that the chamber 10, the fluid circulation tube 20 and the outside of the temperature control unit 30 is surrounded by a heat insulating material 60 for blocking the heat of external air. .

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