UA98594C2 - Method and device for determination of characteristics of reliability of a thermo-electric cooler - Google Patents

Abstract

The invention relates to refrigeration engineering, in particular to thermo-electric cooling devices principle of operation of which is based on Peltier effect. A method for determination of characteristics of reliability of a thermoelectric cooler includes supply of direct current to inputs of thermoelectric cooler with determination of cold productivity by temperature drop between the hot and cold electrodes. On the cold electrode of the thermoelectric cooler that operates with circuit of thermo-stabilization one generates a heat pulse of normalized energy with power 5-10% of maximum cold productivity and with duration equal to heat time constant – 2-4 s, and after its termination one analyses temperature change on the cold electrode of thermoelectric cooler, with making decision on work capacity of thermoelectric cooler under condition that temperature on the cold electrode comes to the value of initial temperature of heat pulse of normalized energy supply, and by the value of constant temperature on the cold electrode after the end of transition process of thermo-stabilization and comparison of feeding current of the thermoelectric cooler with collected before evidences at that very conditions one predicts probability that reliability parameters go out of permitted boundaries. A device for determination of characteristics of reliability of the thermoelectric cooler includes a thermo-electric cooler that includes the hot and the cold electrodes, with temperature sensor applied to the cold electrode, system of thermo-stabilization of the cold electrode of the thermoelectric cooler connected by feedback circuit to temperature sensor, at that the device additionally includes a block for formation of test pulse, a heater connected to the thermoelectric cooler applied to the cold electrode, and microprocessor analyzer, at that the input of the first analog-to-digital converter of that one is connected to the temperature sensor, the input of the second analog-to-digital converter is connected to the output of the thermo-stabilization system, control output of the microprocessor analyzer is connected to the start input of the block for formation of the test pulse, and information output of the microprocessor analyzer is the output of the decision making device for prediction of characteristics of reliability of the thermoelectric cooler. Control of state of thermoelectric cooler in process of operation is achieved, with determination of characteristics of reliability by presence of degradation of parameters of thermoelectric cooler and its functional environment.

Description

The invention relates to refrigeration equipment, in particular, to thermoelectric cooling devices, the principle of operation of which is based on the Peltier effect.

Thermoelectric cooling devices of this type consist of serially connected p- and n-type semiconductors creating p-p and p-p junctions. Each of the transitions has thermal contact with ceramic plates connected to radiators. As a result of the passage of a constant electric current of a certain polarity, a temperature difference is formed between the ceramic coatings of the Peltier module, while one coating is heated (hot electrode), and the other absorbs heat (cold electrode) (see Anatichuk L.IM. Thermozlement and thermoelectric devices. Kyiv, Naukova dumka, 1979, - 768 p).

The spheres of application of thermoelectric devices are extremely wide (for example, devices for physiotherapy, for air conditioning in a car, etc.), which is due to their small dimensions and weight, the absence of moving components, low inertia, easy control of cooling capacity, the ability to work in a wide range of mechanical and climatic conditions. operating loads.

Taking into account the specific requirements for cooling objects has led to the creation of a significant number of thermoelectric coolers that have, in comparison with standard ones, increased operational characteristics or reliability parameters (see pat. pat. KO Mo 2155917, IPC EB258 21/02, publ. 10.09.2000).

At the same time, the expansion of the scope of use of thermoelectric cooling faces the problem of ensuring the reliability of Peltier modules. First of all, this applies to difficult operating conditions, when it is necessary to work at the limit of the capabilities of the materials of the components from which they are made (see Zhadnov V.V., Sarafanov A.V. Quality control in the design of thermally loaded radioelectric devices. - M.: SOLON-Press, 2004. - 464 p.).

To increase the reliability of thermoelectric coolers, mainly parametric methods of increasing reliability will be used, which is the basic design principle.

However, for complex operating conditions, parametric approaches are insufficient, since these methods solve only part of the problem of ensuring reliability, namely, the quality of design and manufacturing of products. z The use of structural redundancy methods increases the reliability parameters of problem elements and the system as a whole (see Polovko A.M., Gurov S.V. Fundamentals of reliability theory. Praktikum. - St. Petersburg: BHV-Petersburg, 2006. - 560 p.).

At the same time, the main principles included in the structural methods of increasing reliability are based exclusively on probabilistic methods, that is, on the average statistical characteristics of element failures under standard conditions, and practically do not take into account the conditions of operation and load. The spread of failure intensities of a specific element and its average statistical model in real operating conditions can differ by tens of times.

The accumulation of statistical data on component failures shows that the spread of failures over time relative to the average statistical value is large and there is an urgent need for methods that ensure the prediction of the reliability characteristics of a specific element based on its actual state (see Aleksandrovskaya L.N., Afanasyev ALP., Lysov A. .A. Sovremen'e metod'i obezapennosti bezotkaznosti slokh'nyi tekhnicheskih sistem (Modern methods of ensuring the reliability of complex technical systems. - M.: Logos, 2001. - 208 p.). This task is part of the fundamental problem of ensuring trouble-free operation of technical systems. Therefore, the modern direction of designing reliable systems from elements with a finite level of failure intensity is not only the probabilistic assessment of the failure of elements from the working condition, but also the control of the working condition of critical components during operation, which is aimed at ensuring the prediction of the possible failure of the component according to the nature of inevitable degradation processes, affecting its reliability parameters.

BO The closest to the claimed invention is the method in which it is proposed to predict the reliability indicators of single-stage thermoelectric cooling devices. The method consists in the fact that current is supplied from the thermostabilization system and the temperature difference between its cold and hot electrodes is determined, the cooling capacity of the thermoelectric cooler is determined by the ratio of the current and temperature values, the reliability indicators are calculated depending on the current operating mode of the thermocouple, the amount of current load, increased and low temperature of the environment (see Zaikov V.P., Kinshova L.A., Moiseev V.F. Forecasting of reliability indicators of thermoelectric cooling devices. Book 1. Single-cascade device.

Odessa: Polytechperiodical, 2009. - 120 p). The main advantages of the prototype from the point of view of reliability are the possibility of rational design of thermoelectric devices when using standard modules, taking into account the ability of the radiator to remove heat, determining the probability of failure-free operation depending on the operating and load modes, as well as controlling the intensity of failures by variation of the operating current.

This method is selected as a prototype method.

The prototype and the claimed method have the following common features: - a direct current from the thermal stabilization system is applied to the input of the thermoelectric cooler; - determine the temperature difference between the cold and hot electrodes.

At the same time, the proposed method of determining the reliability indicators of thermoelectric cooling devices, intended for the design of devices in relation to the average operating conditions and modes of operation specified in the technical conditions, does not provide control of performance during operation and predicting the possibility of device failure as a result of the action of external conditions , as well as the possible degradation of transmission characteristics affecting reliability parameters.

A thermoelectric thermostabilization device is known (see O.I. Izyarsky, N.P. Udalov

Thermoelectric elements. M. Znergia, 1970. - 72 p.), containing a thermoelectric cooler, a temperature sensor and a thermal stabilization circuit, containing a thermoelectric cooler, a temperature sensor and a thermal stabilization circuit. This device is selected by the device prototype.

The prototype and the claimed device have the following common features: - a thermoelectric cooler with a temperature sensor applied to the cold electrode; - a thermostabilization circuit connected by a feedback circuit with a temperature sensor on a cold electrode, which forms the operating current of the thermoelectric cooler.

However, the known device cannot reliably and accurately predict the reliability indicators of a thermoelectric cooler.

The invention is based on the task of creating a method that provides control of the state of the thermoelectric cooler during operation and determines reliability indicators in the presence of degradation of the parameters of the thermoelectric cooler and its functional environment using the device necessary for this control.

The task was solved by a group of inventions united by one inventive idea, namely two inventions: a method of determining the reliability indicators of a thermoelectric cooler and a device for its implementation.

In the first invention, the problem is solved by the method of determining the reliability indicators of the thermoelectric cooler, which includes supplying direct current to the inputs of the thermoelectric cooler and determining the cooling capacity based on the temperature difference between the hot and cold electrodes, by generating thermal a pulse of normalized energy with a power of 5-10 906 of maximum cooling capacity and a duration equal to the thermal time constant of the thermoelectric cooler - 2-4 s, and after it ends, the temperature change at the cold electrode of the thermoelectric cooler is analyzed, and a decision is made about the operability of the thermoelectric cooler, provided that the temperature on the cold electrode reached the value of the initial temperature before the application of the thermal pulse of normalized energy, and according to the value - the constant temperature on the cold electrode after the end of the transient process of thermal stabilization and based on the results of comparing the operating current of the power supply of the thermoelectric cooler with previously accumulated similar evidence, the probability of the reliability parameters exceeding the permissible limits is predicted.

What is new in the claimed method is that on the cold electrode of the thermoelectric

BO of a cooler operating with a thermal stabilization scheme, generate a thermal pulse of normalized energy with a power of 5-10 96 of maximum cooling capacity and a duration equal to the thermal time constant of the thermoelectric cooler - 2-4 s, and after its end, the temperature change on the cold electrode of the thermoelectric cooler is analyzed, and make a decision about the performance of the thermoelectric cooler on the condition that the temperature on the cold electrode has reached the value of the initial temperature before the supply of a heat pulse of normalized energy, and according to the value of the constant temperature on the cold electrode after the end of the transient process of thermal stabilization and comparison of the supply current of the thermoelectric cooler with previously accumulated values - predict the probability reliability parameters exceeding permissible limits.

In the second invention, the problem is solved by a device for determining the reliability indicators of a thermoelectric cooler, which contains a thermoelectric cooler that includes hot and cold electrodes, with a temperature sensor applied to the cold electrode, a circuit for thermal stabilization of the cold electrode of the thermoelectric cooler, connected by a feedback circuit with a temperature sensor in that the device additionally contains a test pulse generating unit connected to a heater applied to the cold electrode of a thermoelectric cooler, and a microprocessor analyzer, while the first input of analog-to-digital conversion is connected to the temperature sensor, the second input of analog-to-digital conversion is connected to the output of the thermostabilization circuit, the control output of the microprocessor analyzer, the test pulse formation block connected to the start input, and the information output of the microprocessor analyzer block is the decision-making output of the prediction device indicators of reliability of the thermoelectric cooler.

What is new in the claimed device is that the device additionally contains a test pulse generating unit connected to a heater applied to the cold electrode of the thermoelectric cooler, and a microprocessor analyzer, while the first analog-to-digital conversion input of which is connected to the temperature sensor, the second analog input - digital conversion is connected - to the output of the thermal stabilization circuit, the control output of the microprocessor analyzer, the test pulse formation block connected to the start input, and the information output of the microprocessor analyzer block is the output of the decision-making device for predicting the reliability indicators of the thermoelectric cooler.

The method is implemented as follows.

A joule heat pulse with a power of 5-10 96 of the maximum cooling capacity of the cooler and a duration equal to the thermal steel of the cooler (2-4 seconds) is applied to the cold electrode of the thermoelectric cooler. Deviation from the set temperature of the cold electrode of the thermoelectric cooler is considered by the thermostabilization circuit as a disturbance, and it works out the cold electrode temperature recovery mode. An increased current is supplied to the current inputs of the thermoelectric cooler to compensate for the imbalance. z Since the object of control is thermal, it can be described by a linear inertial link

Kk of the first order (Tr--1)u-Kh with the transmission k characteristic UM(r)--- (see Yurevych

Tr-n1

WOULD. Theory of automatic control. L.: Znergia, 1969. - 375 p). The transient characteristic of such a link is the exponent n) -kI-ehri- Ж), and the value of the time constant T determines the inertia of the link. The inertia of the link is well described by thermal objects with homogeneous

ZB characteristics, which include thermoelectric cooling devices with radiators. Since the short-term test thermal effect is significantly less than the thermal inertia of the cooling system with a radiator, the above considerations regarding the transmission characteristics can be considered correct.

The management of thermoelectric cooling devices is made in such a way as to be able to compensate for the additional heat impulse coming from the outside, therefore, there should be an excess of cooling capacity compared to the normal operating mode. Deviation control systems are usually modeled by an oscillating link of the second order (tr with Tor--1)u-Kx, and T, and T are connected by the condition: E- i -1, and the roots of the characteristic 1 equation are complex. The equation of the stable mode of the oscillating link has the same form as that of the inertial link: ust-KhXst. If we introduce the notation E--2, then it is possible to determine the transient 2 characteristics of the oscillating link for different values of 5. At small values of the quantity (5-0.1), the maximum growth rate of П() is observed, which reaches a constant value of К, an almost twofold excess is achieved of this value, and then an oscillatory damping process of a relatively constant value begins. At 2-0.4, the growth rate of the transient

The BO of the process decreases, the oscillations decay faster, but the overregulation also decreases. At

E-1 there is no oscillatory process, but the time to reach a stationary value increases significantly (see ibid.).

From the above, it follows that the difference in the behavior of the inertial link (the link of perception and accumulation of external heat flow) and the static oscillating link of the second order of temperature stabilization (the thermal stabilization scheme due to the variation of the cooling capacity of the thermoelectric cooler) can be used to make a decision about the performance of the cooler. With a working thermoelectric cooler, the absorption of an external thermal pulse leads to an increase in the temperature of the cold electrode.

This information through the feedback circuit is sent to the temperature control circuit and the operating current changes to increase the cooling capacity of the cooler. When compensating the external heat flux, some overregulation occurs, since the compensation term is critical for such devices. This oscillatory process with overcompensation serves as initial information about the performance of the thermoelectric device. If the thermoelectric device is faulty, the oscillating process will not be observed.

The temperature of the cold electrode when absorbing Joule heat will first rise, and then due to the heat capacity of the surrounding components it may decrease slightly, but it will not reach the stabilization temperature and an oscillating process relative to the stabilization temperature will be observed, which can serve as a basis for making a decision about the failure of a thermoelectric cooler with a thermal stabilization scheme .

The stable mode on the cold electrode after the action of the test thermal pulse of the disturbance and the completion of the thermostabilization cycle is used to determine the value of the power supply current under constant external conditions. Comparing it with previously obtained values under the same conditions allows us to reveal the nature of the gradation processes in the thermoelectric cooler. Constant external conditions can be provided by blocking the incoming heat flow, which for infrared systems is achieved by diaphragming the incoming radiation for the duration of the test.

Methods of signal analysis have been worked out in depth (see I. Haydshev. Analysis and processing of data: a special reference book. - St. Petersburg: Peter, 2001. - 752 p.), so the task of detecting a signal fluctuation relative to a constant, moreover, synchronized with a test thermal pulse, does not represent a technical problem. This also applies to the construction of the transmission characteristic change curve over time based on the obtained data. Mathematical methods of decision-making and algorithms for their implementation are also known (see V.I. Bodrov, T.Ya. Lazareva,

Martemyanov Yu.F. Mathematical methods of making decisions: Teaching manual. Tambov: Tambo Publishing House. Mr. technical University, 2004. - 124 p.). Microprocessor means of implementing the processing of such signals in real-time operation of the system are known, they are widely represented on the market at an affordable price policy (see Pavlov A.I. Microprocessor control systems. Odessa, 2004. - 386 p.).

Therefore, the proposed method of determining the performance of a thermoelectric cooling device with a thermal stabilization scheme is technically implemented by existing technical means and does not require additional inventions for its implementation.

Comparison of the proposed method with the prototype shows that the method of supplying a thermal pulse to a cold electrode is known. Methods of signal processing by microprocessor devices are also known. However, in a new set, they make it possible to acquire a new non-obvious property, namely, to determine the performance of a thermoelectric cooler based on the fluctuating characteristic of the temperature on the cold electrode, and based on the constant value of the temperature after the end of the transition process, to establish the nature of the transmission coefficient degradation processes and to predict the probable time of its failure , which meets the "novelty" criterion.

A comparison of the proposed method with the prototype and analogs shows that the main ways to increase the reliability parameters of thermoelectric coolers are the quality of design and manufacturing of products, and the reduction of heat loss. In the proposed method, the function of adding a thermal pulse to the cold electrode is implemented, which together with the processing of temperature dependence allows to acquire a new property - the prediction of the reliability parameters of the thermoelectric cooler. This meets the "substantial distinctions" criterion.

BO The positive effect of the implementation of the proposed method consists in the possibility of automatically determining the performance of thermoelectric coolers, as well as predicting the probability of its failure and taking measures for this in a timely manner. This makes it possible to make timely decisions regarding the replacement of failed products and thereby reduce equipment downtime, as well as to predict the probability of a possible system failure, preventing the accompanying more expensive and more serious consequences of sudden system failures.

The device for implementing the proposed method is shown in the drawing. The device for predicting reliability indicators of a thermoelectric cooler includes: 1 - a thermoelectric cooler; 6о 2 - hot electrode of the thermoelectric cooler;

C - cold electrode of the thermoelectric cooler; 4 - temperature sensor; - thermal stabilization scheme; 6 - test pulse generation unit; 5 7 - heater; 8 - microprocessor analyzer.

The device (see drawing) contains a thermoelectric cooler 1 with hot 2 and cold

With the electrodes of the thermoelectric cooler, the temperature sensor 4, located on the cold From the electrode of the thermoelectric cooler 1, is designed to receive feedback for the thermal stabilization circuit 5. The outputs of the thermal stabilization circuit 5 are connected to the power inputs of the thermoelectric cooler 1. To ensure the possibility of predicting the reliability parameters of the thermoelectric cooler , it includes a unit for generating a test pulse 6 connected to a heater 7, which is applied to the cold electrode C of the thermoelectric cooler 1 by the method of thin-film technology. In addition, the device contains a microprocessor analyzer 8, the input of the first analog-to-digital converter of which is connected to the temperature sensor 4 , the input of the second analog-to-digital converter is connected to the output of the thermostabilization circuit 5, the control output of which is connected to the start input of the test pulse formation block b, and its information output is the output of the forecast device bathing

The device works like this.

The thermoelectric cooler 1 is supplied with operating current from the thermostabilization circuit 5, the feedback circuit of which receives a signal about the temperature of the cold C electrode of the thermoelectric cooler from the temperature sensor 4, manufactured using thin-film technology in the form of a metal (for example, tantalum) resistance sensor. So, blocks 1, 4, 5 collectively form a classic system for stabilizing the temperature regime of the cooler with deviation feedback.

When a start pulse is supplied from the microprocessor analyzer 8, for which a microcontroller with two analog inputs is used, a pulse of a given current and a duration in the range of 1-4 seconds is generated at the output of the test pulse forming unit. It is connected to the heater 7, which is made according to the same technology and from the same material as the temperature sensor 4, but which has a wider path (10-20 times), which allows a larger current to pass through it. The physical and technological foundations of the technology and construction of thin-film resistors are known (see A.A. Babnikin Zlektronika i mikrozlektronika. Physico-technological basics. -

M. FIZMATLYT, 2006. - 424 p., Design and technology of microcircuits. Course design / Koledov L.A., Volkov V.A., Dokuchaev N.Y. under the editorship L.A. Christmas - M.: Viessh. Shk., 1984. - 231 p.). The heat released by the heater 7 heats the cold electrode C of the thermoelectric cooler. The power of the thermal pulse is 05-1095 of the maximum cooling capacity of the cooler, which is enough to conduct a qualitative analysis of the transient characteristic and minimize the period of recovery of the temperature regime of the cold electrode. The thermostabilization scheme begins to work out the mode of restoring the temperature of the cold electrode 3, that is, it supplies an increased current to the thermoelectric cooler 1, producing a higher cooling capacity of the cooler. The process of restoring the constant value of the temperature on the cold electrode C with a working thermoelectric cooler passes a damping oscillation cycle through the crossing point of the temperature of the constant value, overregulation when the temperature drops below the constant value and underregulation, approaching the constant value. Microprocessor analysis of the signal relative to the time of the disturbance (delivery of the test thermal pulse) does not pose a problem, since the modeling and programming of transient processes is presented in the literature (see

Pavlov A.I. Microprocessor systems! management Odessa, 2004. - 386 p.). Upon availability

Because of signal fluctuations relative to a constant value, the microprocessor analyzer makes a decision about the performance of the controlled thermoelectric cooler. If a thermoelectric cooler with a thermal stabilization circuit does not reach a stable temperature level, a decision is made regarding the inoperability of the cooler.

Forecasting the possibility of failure of the thermoelectric cooler in the case of continuous failures due to degradation of characteristics is carried out after establishing a constant temperature value on the cold electrode and comparing the operating current of the thermoelectric cooler with similar values in previous tests.

In order to exclude the influence of external actions on the results, the incoming flow to the cold electrode is blocked by a diaphragm at the moment the start pulse is applied to the unit 60 of the test pulse 6 until a stable process is established (not shown in the drawing).

An example of a specific application of the claimed method using the claimed device.

Making a decision about the efficiency is based on the analysis of the temperature change on the cold electrode - when a stationary temperature is reached after receiving a test heating pulse, a decision is made about the efficiency of the thermoelectric cooler.

If the temperature of the cold electrode of the cooler has not reached a stationary value within 3-5 thermal constants of the cooler with a stabilization circuit (the reliability of which is significantly higher than the cooler, since it is not in a heat-loaded mode), a decision is made about its inoperability.

Claims (2)

FORMULA OF THE INVENTION 1. The method of determining the reliability indicators of a thermoelectric cooler, which includes supplying direct current to the inputs of the thermoelectric cooler and determining the cooling capacity based on the temperature difference between the hot and cold electrodes, which is characterized by the fact that a thermal pulse is generated on the cold electrode of the thermoelectric cooler operating with a thermostabilization scheme of normalized energy with a capacity of 5-10 95 of maximum cooling capacity and a duration equal to the thermal time constant - 2-4 s, and after it ends, the temperature change at the cold electrode of the thermoelectric cooler is analyzed, and a decision is made about the performance of the thermoelectric cooler, provided that the temperature at the cold electrode reached the value of the initial temperature before the supply of a thermal pulse of normalized energy, and according to the value of the constant temperature on the cold electrode after the end of the transient process of thermostabilization and comparison of the supply current of the thermoelectric cooler with the previously accumulated values of the supply current, obtained under the same conditions, predict the probability of the reliability parameters exceeding the permissible limits. 2. A device for determining the reliability indicators of a thermoelectric cooler, containing a thermoelectric cooler that includes hot and cold electrodes, with a temperature sensor applied to the cold electrode, a thermal stabilization circuit of the cold electrode of the thermoelectric cooler, connected by a feedback circuit to the temperature sensor, which differs in that the device additionally contains a test pulse forming unit connected to the thermoelectric cooler applied to the cold electrode of the heater, and a microprocessor analyzer, while the input of the first analog-to-digital converter is connected to the temperature sensor, the input of the second analog-to-digital converter is connected to the output of the thermal stabilization circuit, the control output of the microprocessor analyzer is connected to the start input of the test pulse forming block, and the information output of the microprocessor analyzer is the output of the decision-making device for determining reliability indicators thermoelectric cooler.