JP6493176B2 - Cooler - Google Patents

Description

  The present invention relates to a cooler that causes self-excited vibration of a refrigerant fluid and cools a heating element in accordance with the self-excited vibration.

  Conventionally, a heating unit that heats and vaporizes a part of the refrigerant fluid enclosed in the tubular housing space by heat from the heating element, and a cooling unit that cools and liquefies the refrigerant fluid vaporized in the heating unit, , There is a cooler with.

  In this cooler, the refrigerant fluid is vaporized by the heating unit, and the refrigerant fluid is liquefied by the cooling unit to repeat self-excited oscillation of the refrigerant fluid in the accommodation space, and the heating element is cooled by the self-excited oscillation. It is configured as follows.

  In such a cooler, for example, when the heating element (for example, a semiconductor element) is operated or not operated, the amount of heat generated by the heating element becomes uneven, and the self-excited vibration is stabilized. Will not be done. Further, even when the temperature of the heating element rises very slowly, there is a case where a force sufficient to generate self-excited vibration is not generated and the self-excited vibration is not stably performed.

  As described above, when the self-excited vibration is not stably performed, the refrigerant fluid does not boil in a timely manner, and the self-excited vibration stops. And there exists a problem that the temperature of a semiconductor element will rise, without cooling a semiconductor element.

  Therefore, when the temperature of the heating element exceeds a predetermined temperature threshold, there is one that promotes self-excited vibration by giving a pulsed pressure fluctuation to the refrigerant in the accommodation space (for example, , See Patent Document 1).

JP 2014-214906 A

  However, the apparatus described in Patent Document 1 gives self-excited vibration by giving pulsed pressure fluctuations to the refrigerant in the housing space when the temperature of the heating element exceeds a predetermined temperature threshold. Configured to promote. In other words, the apparatus described in Patent Document 1 does not give pulsed pressure fluctuations to the refrigerant in the housing space unless the temperature of the heating element exceeds a predetermined temperature threshold. Thus, there is a problem that the deterioration of the heating element is promoted and a problem that the self-excited vibration is delayed.

  The present invention has been made in view of the above problems, and it is an object of the present invention to more reliably and quickly promote self-excited vibration and to suppress a temperature rise of a heating element.

In order to achieve the above object, the invention according to any one of claims 1 to 7 is a heating unit that heats and vaporizes a part of the refrigerant fluid sealed in the tubular housing space by heat from the heating element (12). 141) and a cooling unit (142) for cooling and liquefying the refrigerant fluid vaporized by the heating unit. Then, by repeating the vaporization of the refrigerant fluid by the heating unit and the liquefaction of the refrigerant fluid by the cooling unit, the refrigerant fluid is self-excited in the accommodation space, and the heating element is cooled in accordance with the self-excited vibration. Furthermore, a movable part (28) that displaces in the axial direction of the accommodating space and applies pressure fluctuation to the refrigerant fluid, and a detection part (S104, S300, S604, S700) that detects at least one of the displacement of the movable part and the pressure of the refrigerant fluid. And a self-excited vibration promoting unit (32) that applies pressure fluctuation to the refrigerant fluid so as to promote the self-excited vibration of the refrigerant fluid based on at least one of the displacement of the movable unit and the pressure of the refrigerant fluid detected by the detecting unit. It is equipped with.

  According to such a configuration, the detection unit (S104, S300, S604, S700) detects at least one of the displacement of the movable unit and the pressure of the refrigerant fluid, and the self-excited vibration promoting unit is detected by the detection unit. Since the pressure fluctuation is given to the refrigerant fluid so as to promote the self-excited vibration of the refrigerant fluid based on at least one of the displacement of the movable part and the pressure of the refrigerant fluid, the self-excited vibration can be promoted more reliably and quickly, and the heating element Temperature rise can be suppressed.

  In addition, the code | symbol in the bracket | parenthesis of each means described in this column and the claim shows the correspondence with the specific means as described in embodiment mentioned later.

It is sectional drawing which shows the whole structure of the cooler which concerns on 1st Embodiment of this invention. It is a flowchart which shows the control processing of the control apparatus of the cooler which concerns on 1st Embodiment. It is a time chart for demonstrating the control processing shown to the flowchart of FIG. It is a flowchart which shows the control processing of the control apparatus of the cooler concerning 2nd Embodiment. It is a time chart for demonstrating the control processing shown to the flowchart of FIG. It is a flowchart which shows the control processing of the control apparatus of the cooler which concerns on 3rd Embodiment. It is a time chart for demonstrating the control processing shown to the flowchart of FIG. It is a flowchart which shows the control processing of the control apparatus of the cooler which concerns on 4th Embodiment. It is a time chart for demonstrating the control processing shown to the flowchart of FIG. It is a flowchart which shows the control processing of the control apparatus of the cooler which concerns on 5th Embodiment. It is a time chart for demonstrating the control processing shown to the flowchart of FIG. It is a figure which shows the whole structure of the cooler which concerns on 6th Embodiment of this invention. It is a flowchart which shows the control processing at the time of starting of the control apparatus of the cooler concerning a 6th embodiment. It is a flowchart which shows the control processing at the time of the self-excited vibration attenuation | damping of the control apparatus of the cooler concerning 6th Embodiment. It is a figure showing the amplitude of the refrigerant pressure when the self-excited vibration of the cooler concerning a 7th embodiment attenuates.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, the same or equivalent parts are denoted by the same reference numerals in the drawings.

(First embodiment)
FIG. 1 is a diagram illustrating an overall configuration of a cooler 10 according to the present embodiment, and is illustrated in cross section. The cooler 10 cools the heating element 12 using the refrigerant sealed in the cooler 10. The refrigerant in the cooler 10 is a fluid that is liquid at room temperature and boils when heated by the heating element 12. As shown in FIG. 1, the cooler 10 includes a refrigerant container 14, a telescopic part 28, and a self-excited vibration promoting part 32.

  The heating element 12 is a member that is cooled by the cooler 10, and specifically, is a semiconductor element or the like that needs to be cooled. In the present embodiment, a power module (not shown) of an inverter that drives a motor serving as a power source for an electric vehicle, a hybrid vehicle, or the like is cooled as the heating element 12. The inverter is a main component constituting a PCU (Power Control Unit) (not shown). The PCU includes an ECU and the like in addition to the inverter.

  A tubular tubular space 22 in which the refrigerant is accommodated is formed inside the refrigerant container 14. One end of the tubular space 22 is closed, but the other end communicates with an expansion / contraction space 28 a formed in the expansion / contraction part 28. That is, the tubular space 22 and the expansion / contraction space 28a are integrated to form a tubular accommodation space 24 that encloses the refrigerant.

  In addition, the refrigerant container 14 has a heating unit 141 and a cooling unit 142. The heating unit 141 and the cooling unit 142 are arranged side by side from one end side of the tubular space 22 along the longitudinal direction of the tubular space 22.

  A heating element 12 is disposed in the heating unit 141. Specifically, the heating element 12 is accommodated in a heating portion tubular space 221 that is a portion belonging to the heating portion 141 in the tubular space 22.

  The electrical terminals 12 a and 12 b of the heating element 12 protrude from the heating unit 141. The electric terminals 12a and 12b of the heating element 12 are connected to an ECU in the PCU. The heating element 12 generates heat when energized from the ECU in the PCU.

  With such a configuration, the heating unit 141 causes a part of the refrigerant enclosed in the accommodation space 24 to boil and vaporize by the heat from the heating element 12. Specifically, the refrigerant in the heating portion tubular space 221 is superheated and vaporized.

  The cooling unit 142 includes a cooling device 142a for cooling the refrigerant, and the cooling device 142a cools and liquefies the refrigerant in the cooling unit tubular space 222, which is a portion belonging to the cooling unit 142 in the tubular space 22. .

  Specifically, the cooling device 142 a is configured by a large number of cooling fins provided around the cooling unit tubular space 222. The cooling device 142a cools the refrigerant in the cooling section tubular space 222 by exchanging heat with the outside air.

  The cooling section tubular space 222 is configured by a pipe having a very small pipe cross-sectional area perpendicular to the longitudinal direction thereof. Therefore, when the refrigerant gas-liquid interface 26 exists in the cooling unit tubular space 222, the gas-liquid interface 26 is orthogonal to the longitudinal direction of the cooling unit tubular space 222 due to the surface tension of the refrigerant regardless of the direction of gravity. It is maintained so as to face the direction to do. That is, in the longitudinal direction of the cooling unit tubular space 222, the gas refrigerant exists on the heating unit 141 side with the gas-liquid interface 26 as a boundary, and the liquid refrigerant exists on the opposite side.

  For example, the gas-liquid interface 26 moves in the other end direction of the tubular space 22, that is, in the left direction in FIG. 1 as the volume of the gas refrigerant increases as the refrigerant is heated by the heating unit 141. Then, the cooling unit 142 also cools the liquid refrigerant, but also cools and condenses the gas refrigerant vaporized by the heating unit.

  The expansion / contraction part 28 is comprised, for example by the bellows etc., and expands / contracts in the longitudinal direction of the cooling unit tubular space 222. The expansion / contraction part 28 is a movable part that is displaced in the axial direction of the accommodation space 24 and applies pulsed pressure fluctuations to the refrigerant fluid. When the expansion / contraction part 28 expands / contracts, the expansion / contraction space 28a expands / contracts in the longitudinal direction of the cooling unit tubular space 222 accordingly. The expansion space 28a is filled with a liquid refrigerant. The expansion / contraction part 28 is fixed to the refrigerant container 14 at one end on the refrigerant container 14 side. A linear actuator 35 is disposed at the other end of the expansion / contraction part 28 on the refrigerant container 14 side.

  Further, the end of the expansion / contraction space 28a on the refrigerant container 14 side communicates with the tubular space 22, and the end of the expansion / contraction space 28a on the linear actuator 35 side is closed. Therefore, when the refrigerant in the tubular space 22 flows into the expansion / contraction space 28a, the expansion / contraction space 28a extends and the end of the expansion / contraction portion 28 on the linear actuator 35 side moves to the linear actuator 35 side, that is, to the left in FIG. Conversely, when the refrigerant in the expansion / contraction space 28a flows into the tubular space 22, the expansion / contraction space 28a contracts and the end of the expansion / contraction portion 28 on the linear actuator 35 side moves to the refrigerant container 14 side, that is, to the right in FIG.

  The self-excited vibration promoting unit 32 includes a linear actuator 35 having a permanent magnet 35a and a coil 35b, a power source 31, and a control device 30.

  The linear actuator 35 has a permanent magnet 35a and a cylindrical coil 35b. The linear actuator 35 is a device that projects a permanent magnet 35 a toward the extendable portion 28 in response to a signal from the control device 30.

  The permanent magnet 35a is supported inside the coil 35b via a support member (not shown) so as to be able to reciprocate in the axial direction of the coil 35b. The coil 35b is fixed to a case (not shown).

  The linear actuator 35 has a return spring (not shown) that urges the permanent magnet 35a toward the anti-expandable portion. By this spring member, the permanent magnet 35a is urged toward the opposite side of the stretchable part.

  When a predetermined current flows through the coil 35b, a magnetic field is generated around the coil 35b, and a force for displacing the permanent magnet 35a toward the telescopic portion 28 acts by this magnetic field. When the permanent magnet 35a is displaced toward the expansion / contraction part 28 against the return spring, the expansion / contraction part 28 contracts, and the expansion / contraction space 28a also contracts in the longitudinal direction of the cooling unit tubular space 222, and the refrigerant fluid is pressurized. The

  Thus, the linear actuator 35 pressurizes the expansion / contraction part 28 by flowing a predetermined current through the coil 35 b in accordance with an instruction from the control device 30. When the current to the coil 35b is interrupted, the magnetic field around the coil 35b disappears, and the permanent magnet 35a is biased by the return spring and returns to its original position.

  The power supply 31 controls the amount of current flowing through the coil 35b in accordance with an instruction from the control device 30. The power supply 31 has a function of detecting an electromotive force generated in the coil 35b by electromagnetic induction when the expansion / contraction part 28 is displaced. Specifically, the power supply 31 detects a current generated in the coil 35 b and outputs a current value of the detected current to the control device 30.

  The control device 30 is composed of a well-known microcomputer comprising a CPU, ROM, RAM, etc. and its peripheral circuits, and executes various control processes in accordance with a computer program stored in advance in the ROM.

  As shown in FIG. 1, the controller 30 receives a signal from the heating element temperature sensor 13 for detecting the temperature of the heating element 12, that is, the heating element temperature, a signal from the refrigerant pressure sensor 36 for detecting the refrigerant pressure, and the like. Is done.

  The heating element temperature sensor 13 detects the heating element temperature as described above. Specifically, the heating element temperature sensor 13 is provided on the surface of the heating element 12 and detects the surface temperature of the heating element 12 as the temperature of the heating element 12. .

  The refrigerant pressure sensor 36 detects the refrigerant pressure, and outputs a detection signal representing the refrigerant pressure to the control device 30. Specifically, the refrigerant pressure sensor 36 is provided in the heating portion tubular space 221 and detects the pressure in the heating portion tubular space 221 as the refrigerant pressure. In short, the refrigerant pressure sensor 36 detects the internal pressure of the accommodation space 24.

  Further, a PCU signal is input to the control device 30 from a PCU (not shown) via a communication line. The PCU signal includes an inverter on / off signal as a signal indicating whether or not the heating element 12 is operating.

  In the cooler 10 configured as described above, when the liquid refrigerant in the heating section tubular space 221 is heated and boiled by the heating element 12, the volume of the gas portion of the refrigerant increases, and at the same time, the volume of the entire refrigerant increases. . Then, when the volume of the gas portion of the refrigerant increases to some extent, for example, when the gas-liquid interface 26 enters the cooling portion tubular space 222 as shown in FIG. 1, the cooling portion 142 cools and condenses the refrigerant gas portion.

  When the gas portion is reduced by condensing the gas portion of the refrigerant, the volume of the entire refrigerant is reduced at the same time, the gas-liquid interface 26 of the refrigerant is displaced toward the heating portion tubular space 221 side, and the expansion / contraction portion 28 is contracted. And a part or all of heating element 12 comes to be immersed in a liquid refrigerant. When the heating element 12 is immersed in the liquid refrigerant, the liquid refrigerant in the heating section tubular space 221 again boils and evaporates as described above.

  As described above, in the cooler 10, the heating unit 141 and the cooling unit 142 cause the gas-liquid interface 26 of the refrigerant to self-excited in the accommodation space 24 by causing the refrigerant to repeat evaporation and condensation. In short, the refrigerant is self-excited and vibrated in the accommodation space 24. Further, since the expansion / contraction part 28 expands and contracts to absorb the volume change of the whole refrigerant due to the self-excited vibration of the refrigerant, it functions as a vibration absorption part that absorbs the volume change of the whole refrigerant. Furthermore, since the expansion / contraction part 28 has a predetermined spring constant, a reaction force corresponding to the expansion / contraction amount is generated toward the balance point in the expansion / contraction direction of the expansion / contraction part 28 to assist self-excited vibration of the refrigerant. Fulfill.

  Since the self-excited vibration of the gas-liquid interface 26 uses each inertial force of the refrigerant and the expansion / contraction part 28, for example, the gas-liquid interface 26 at the beginning of the heat generation of the heating element 12 becomes the heating part 141 and the cooling part 142. May remain stationary without self-excited vibration. Therefore, the control device 30 of the present embodiment performs a control process that prevents the self-excited vibration of the gas-liquid interface 26 from stopping.

  Next, with reference to FIG. 2 and FIG. 3, the control process of the control apparatus 30 of this embodiment is demonstrated. FIG. 2 is a flowchart of the control device 30 of the present embodiment. The time chart of FIG. 3 is, in order from the top, (a) heating element temperature, (b) refrigerant pressure, (c) pressure applied by the self-excited vibration promoting unit 32, (d) position of the gas-liquid interface 26 of the refrigerant, e) The detected power generated in the coil 35b is shown.

  In the time chart of FIG. 3, the time when the control device 30 starts the control process shown in FIG. 2 is shown as time zero. The control device 30 performs the processing shown in FIG.

  First, the control device 30 determines whether or not the heating element 12 has started operating (S100). Specifically, it is determined whether or not the heating element 12 has started operating based on an on / off signal of an inverter included in the PCU signal. Here, when the heating element 12 has stopped operating, the determination in S100 is NO, and the determination in S100 is repeated.

Before the heating element 12 starts to operate, the temperature of the heating element 12 is low as shown in FIG. 3A, and as shown in FIG. All the refrigerant in the section 28 is a liquid refrigerant. In FIG. 3D, the vertical axis represents the position of the gas-liquid interface 26 of the refrigerant. The position of the gas-liquid interface 26 of the refrigerant substantially coincides with the position of the end portion on the self-excited vibration promoting portion 32 side of the expansion / contraction portion 28. For example, when the position of the gas-liquid interface 26 of the refrigerant is displaced in the left direction in FIG. 1, the expansion / contraction part 28 extends and the position of the end part on the self-excited vibration promoting part 32 side in the expansion / contraction part 28 is also displaced in the left direction in FIG. To do. Accordingly, the position of the self-excited vibration promoting portion 32 is also displaced in the left direction in FIG. In FIG. _3D , the position of the gas-liquid interface 26 when the refrigerant in the refrigerant container 14 and the expansion / contraction part 28 is all liquid refrigerant is shown as _xmax .

When the inverter as the heating element 12 starts to operate by energization from the ECU in the PCU, and the inverter on / off signal is input from the ECU in the PCU to the control device 30, the control device 30 is based on the on / off signal of the inverter. Then, it is determined that the heating element 12 is operating, and then the self-excited vibration promoting unit 32 is operated (S102). Specifically, as shown in FIG. 3C, the self-excited vibration promoting unit 32 is operated so that the pressure applied to the expansion / contraction unit 28 becomes the pressure _Pa2 . In this manner, the self-excited vibration promoting unit 32 is controlled so that the expansion / contraction unit 28 gives a pressure fluctuation to the refrigerant fluid.

That is, the linear actuator 35 is driven so that the pressing force _Pa2 is applied to the expansion / contraction part 28 that has not been pressurized so far. Specifically, a predetermined current is passed through the coil 35b of the linear actuator 35 to displace the permanent magnet 35a of the linear actuator 35 toward the telescopic portion 28 side. Thus, it takes pressure of the expansion portion 28 pressure _{P a2,} as shown in FIG. 3 (b), the refrigerant pressure becomes a pressure _{P sat2} rises.

Thus, by setting the pressing force of the stretchable portion 28 into pressure _{P a2,} refrigerant boiling _{T sat2} changes. That is, the refrigerant pressure _{P sat} is increased by increasing the pressure _{P a2,} boiling point _{T sat2} refrigerant becomes high. Note that it is possible to control the boiling point T _sat2 refrigerant by changing the applied pressure P _a2.

  Since the heating element 12 continues to operate while the expansion / contraction part 28 is being pressurized in this way, the temperature of the heating element 12 continues to rise as shown in FIG.

Then, the temperature of the heating element 12 at elapsed time t ₁ is reached to the boiling point T _sat2 refrigerant pressurized, so far refrigerant boiling was suppressed by pressurization starts boiling. Further, since the volume of the refrigerant increases when the refrigerant starts to boil, as shown in FIG. 3D, the gas-liquid interface 26 is displaced to the expansion / contraction part 28 side, that is, to the left in FIG. Will grow.

  Next, the control device 30 detects the displacement dx of the gas-liquid interface 26 (S104). The displacement dx of the gas-liquid interface 26 correlates with the displacement of the expansion / contraction part 28. When the expansion / contraction part 28 is displaced, electromotive force (detected power) is generated in the coil 35b by electromagnetic induction as shown in FIG. The control device 30 detects the displacement dx of the gas-liquid interface 26 correlated with the displacement of the expansion / contraction part 28 based on the detection current of the coil 35b detected by the power supply 31. Note that S104 is a detection unit that detects the displacement of the movable part.

Next, the controller 30 determines whether the threshold value dx ₄ is greater than or not the displacement dx is predetermined in the gas-liquid interface 26 (S106).

Here, for example, immediately after the refrigerant has started boiling, as shown in FIG. 3 (d), if the displacement dx of the gas-liquid interface 26 becomes pre threshold dx ₄ defined below, the determination of S106 is NO Then, the process returns to S104.

Moreover, promoted boiling refrigerant, the displacement dx of the gas-liquid interface 26 becomes larger than the threshold value dx ₄ to predetermined determination of S106 becomes YES, and stops the operation of the self-excited vibration acceleration portion 32 (S108). Specifically, as shown in FIG. 3 (c), the elapsed time t ₂ the pressure of the self-excited vibration acceleration portion 32 is set to 0. Specifically, the current flowing through the coil 35b of the linear actuator 35 is set to 0, and the permanent magnet 35a of the linear actuator 35 is displaced to the opposite side of the stretchable part.

Thus, by making the pressurizing force of the self-excited vibration promoting unit 32 zero, the refrigerant boiling point T _sat2 rapidly decreases to a value before pressurization. That is, while the refrigerant temperature is the refrigerant boiling point T _sat2 at the time of pressurization, the refrigerant boiling point T _sat2 is increased by stopping the pressurization to the expansion / contraction part 28 of the self-excited vibration promoting part 32. The refrigerant suddenly boils because it drops rapidly to the previous value.

  And the gas part of a refrigerant | coolant increases, the volume of the whole refrigerant | coolant increases with it, the gas-liquid interface 26 is displaced to the expansion-contraction part 28 side, ie, the left direction of FIG. 1, and the expansion-contraction part 28 is extended. When the gas portion of the refrigerant increases to some extent, for example, when the gas-liquid interface 26 enters the cooling portion tubular space 222 as shown in FIG. 1, the cooling portion 142 cools and condenses the refrigerant gas portion.

  The control process of FIG. 2 as described above is performed, and when the heat generating body 12 starts to generate heat, the refrigerant suddenly boils and evaporates, thereby causing self-excited vibration of the gas-liquid interface 26 of the refrigerant in the accommodation space 24. Can be promoted.

  According to the configuration described above, the cooler includes the detection unit that detects the displacement of the gas-liquid interface 26 as the displacement of the expansion / contraction part 28, and the self-excited vibration promotion unit 32 includes the expansion / contraction part 28 detected by the detection unit. Since the pressure fluctuation is applied to the refrigerant fluid so as to promote the self-excited vibration of the refrigerant fluid based on the displacement, the self-excited vibration can be promoted more reliably and quickly, and the temperature rise of the heating element 12 can be suppressed.

  The detection unit includes a coil 35b that displaces the position of the expansion / contraction part 28, and detects the displacement of the expansion / contraction part 28 based on electric power generated in the coil 35b. That is, since the coil 35b combines the function of displacing the position of the expansion / contraction part 28 and the function of detecting the displacement of the expansion / contraction part 28, the number of components is reduced compared to the case where the two functions are configured separately. be able to.

  In addition, the detection unit detects the displacement of the expansion / contraction unit 28, and the self-excited vibration promotion unit 32 determines that the displacement of the expansion / contraction unit 28 detected by the detection unit is greater than a predetermined value. It is possible to give pressure fluctuations.

  In addition, when the self-excited vibration promoting unit 32 determines that the heating element has started operating based on the external signal, the self-excited vibration promoting unit 32 controls the position of the expansion / contraction unit 28 to increase the pressure of the refrigerant fluid. Self-excited vibration can be stably performed at the start of operation.

  Further, the self-excited vibration promoting unit 32 controls the position of the expansion / contraction unit 28 so that the expansion / contraction unit 28 pressurizes the refrigerant fluid, and then pressurizes the refrigerant fluid based on the displacement amount of the movable unit detected by the detection unit. Since the position of the expansion / contraction part 28 is controlled so as to decrease, the self-excited vibration can be stably performed.

(Second Embodiment)
A cooler according to a second embodiment of the present invention will be described with reference to FIGS. The configuration of the cooler of the present embodiment is the same as the cooler of the first embodiment. The cooler of this embodiment differs in the control process of the control apparatus 30 compared with the cooler of the said 1st Embodiment. Since the self-excited vibration of the gas-liquid interface 26 uses each inertial force of the refrigerant and the expansion / contraction part 28, for example, the gas-liquid interface 26 at the beginning of heat generation of the heating element 12 becomes May remain stationary without self-excited vibration. Therefore, the control device 30 of the present embodiment performs a control process that prevents the self-excited vibration of the gas-liquid interface 26 from stopping.

  FIG. 4 is a flowchart of the control device 30 of the present embodiment. FIG. 5 is a time chart for explaining the control processing shown in the flowchart of FIG. The time chart of FIG. 5 is, in order from the top, (a) heating element temperature, (b) refrigerant pressure, (c) pressure applied by the self-excited vibration promoting unit 32, (d) position of the gas-liquid interface 26 of the refrigerant, e) The operation amount of the self-excited vibration promoting portion is shown. In the time chart of FIG. 5, the time when the heating element 12 starts to operate is displayed as time zero.

  A control process of the control device 30 in FIG. 4 will be described. First, the control device 30 detects the displacement dx of the gas-liquid interface 26 (S200). Specifically, the control device 30 detects the displacement dx of the gas-liquid interface 26 that correlates with the displacement of the expansion / contraction part 28 based on the detection current of the coil 35 b detected by the power supply 31.

Next, the controller 30 determines whether the threshold value dx ₂ larger or not the displacement dx is predetermined in the gas-liquid interface 26, which is detected by S200 (S201). Specifically, it is determined heating element 12 whether to start the operation based on whether the sensed liquid threshold dx ₂ larger or not the displacement dx is predetermined at the interface 26 at S200.

Here, as shown in FIG. 5 (c), if the displacement dx of the gas-liquid interface 26, which is detected is a threshold value dx ₂ below predetermined at S200, the determination in S201 is NO, to S200 Return.

Further, when the displacement dx of the gas-liquid interface 26, which is detected in S200 is larger than the threshold value dx ₂ predetermined, the determination of S201 is YES, then the self-induced vibration acceleration portion 32 Operate (S102). Specifically, as shown in FIG. _5D , the pressure applied to the expansion / contraction part 28 of the self-excited vibration promoting part 32 is set to a pressure _Pa2 .

That is, the elongating and contracting portion 28 was not pressurized to stretch unit 28 until then, the collapsible portion 28 causes pressurized linear actuator 35 to take a pressing pressure of the pressure P _a2.

Thus, the refrigerant boiling point T _sat2 is changed by setting the pressing force _{Pa 2} to the expansion / contraction part 28. That is, increasing the pressure applied to the expansion / contraction part 28 increases the refrigerant pressure P _{sat and} increases the boiling point T _{sat2 of} the refrigerant.

Then, the temperature of the heating element 12 at elapsed time t _a2 is reached the boiling point T _sat2 refrigerant pressurized, so far refrigerant boiling was suppressed by pressurization starts boiling. When the refrigerant starts to boil, the gas-liquid interface 26 moves to the expansion / contraction part 28 side, and the expansion / contraction part 28 extends.

Thereafter, the same processing as in FIG. 2 is performed. That is, whether or not based on the detection power coil 35b detects the displacement dx of the gas-liquid interface 26 (S104), the displacement dx of the gas-liquid interface 26 is greater than the threshold value dx ₃ predetermined detected by the power source 31 Is determined (S106). Note that the threshold value dx ₃ is the same as the threshold value dx ₄ of the first embodiment. When larger than the threshold value dx ₃ displacement dx of the gas-liquid interface 26 reaches a predetermined, it stops the operation of the self-excited vibration acceleration portion 32 (S108).

  In the present embodiment, the same effect obtained from the configuration common to the first embodiment can be obtained as in the first embodiment.

  The control device 30 of the first embodiment determines whether or not the heating element 12 has started to operate based on the on / off signal of the inverter, whereas the control device 30 of the present embodiment includes the expansion / contraction part 28. It is determined whether or not the heating element 12 has started to operate based on the displacement.

  For this reason, compared with the cooler of the first embodiment, it is possible to shorten the period during which the pressure fluctuation is applied to the expansion / contraction part 28, and to reduce the power consumed by the self-excited vibration promoting part 32.

(Third embodiment)
A cooler according to a third embodiment of the present invention will be described with reference to FIGS. The configuration of the cooler of the present embodiment is the same as the cooler of the first embodiment. The cooler of this embodiment differs in the control process of the control apparatus 30 compared with the cooler of the said 1st Embodiment. Since the self-excited vibration of the gas-liquid interface 26 uses the inertial forces of the refrigerant and the expansion / contraction part 28, the self-excited vibration once started is stopped due to fluctuations in the amount of heat generated by the heating element 12. Sometimes. Therefore, the control device 30 performs a control process for preventing the self-excited vibration of the gas-liquid interface 26 from stopping.

  FIG. 6 is a flowchart of the control device 30 of the present embodiment. FIG. 7 is a time chart for explaining the control processing shown in the flowchart of FIG. The time chart of FIG. 7 shows (a) the heating element temperature, (b) the position of the gas-liquid interface, and (c) the pressure applied to the self-excited vibration promoting unit 32 in order from the top. In the time chart of FIG. 7, the time when the heating element 12 starts operating is displayed as time zero.

Control processing of the control device 30 in FIG. 6 will be described. Here, it is assumed that the heating element 12 has already been activated, the temperature of the heating element 12 has reached the boiling point T _sat1 of the refrigerant, and the gas-liquid interface 26 of the refrigerant is self-excited in the accommodation space 24.

  First, the control apparatus 30 detects the displacement dx of the expansion / contraction part 28 (S300). Specifically, the displacement dx of the gas-liquid interface 26 is detected based on the detection power of the coil 35b detected by the power supply 31.

Next, it is determined whether or not the displacement (x ₁ −x ₂ ) / dt ₁ of the gas-liquid interface 26 per unit time dt _{1 is} equal to or greater than a predetermined threshold value dx / dt ₁ (S302). That is, whether the self-excited vibration is attenuated based on whether or not the change amount (x ₁ −x ₂ ) / dt ₁ of the displacement of the gas-liquid interface 26 per unit time dt ₁ is equal to or greater than the threshold value dx / dt ₁ . Determine whether or not.

Here, when the self-excited vibration is stable and the displacement (x ₁ −x ₂ ) / dt ₁ of the gas-liquid interface 26 per unit time dt ₁ is smaller than the threshold value dx / dt ₁ , the determination in S302. NO is determined, and then it is determined whether or not the displacement (x ₁ −x ₂ ) of the gas-liquid interface 26 is equal to or _smaller than a predetermined value x _set (S306). Here, it is determined whether or not the self-excited vibration is attenuated based on whether or not the displacement (x ₁ −x ₂ ) of the gas-liquid interface 26 is equal to or less than a predetermined value x _set .

Here, when the self-excited vibration is stable and the displacement (x ₁ −x ₂ ) of the gas-liquid interface 26 is equal to or less than the predetermined value x _set , the determination in S306 is NO and the process returns to S300.

Also, the self-excited vibration is attenuated, at S306, the displacement of the gas-liquid interface 26 of ₁ per unit time dt _{(x 1} -x 2) / If dt ₁ becomes dx / dt ₁ or more, the determination of S306 is YES, and the self-excited vibration promoting unit 23 is activated (S304). Specifically, the self-excited vibration promoting unit 32 is operated so that the applied pressure to the expansion / contraction unit 28 becomes a higher applied pressure _Pa1 . As a result, the refrigerant pressure P _sat increases and the boiling point T _{sat2 of} the refrigerant increases. Therefore, boiling of the refrigerant is promoted.

Further, when the self-excited vibration is attenuated and the amount of change (x ₁ −x ₂ ) / dt ₁ of the displacement of the gas-liquid interface 26 per unit time dt ₁ becomes equal to or less than the threshold value dx / dt ₁ in S302, The determination in S302 is YES, the self-excited vibration promoting unit 23 is actuated (S304), and this process ends.

  In the present embodiment, the same effect obtained from the configuration common to the first embodiment can be obtained as in the first embodiment.

Further, the control device 30 of the present embodiment is based on whether or not the change amount (x ₁ −x ₂ ) / dt ₁ of the displacement of the gas-liquid interface 26 per unit time dt ₁ is equal to or less than the threshold value dx / dt _1. When it is determined that the self-excited vibration is damped, the self-excited vibration promoting unit 32 is controlled so that the expansion / contraction part 28 gives a pressure fluctuation to the refrigerant fluid.

Further, the control device 30 according to the present embodiment determines that the self-excited vibration is attenuated based on whether or not the displacement (x ₁ −x ₂ ) of the gas-liquid interface 26 is equal to or less than a predetermined value x _set . In this case, the self-excited vibration promoting unit 32 is controlled so that the expansion / contraction unit 28 gives a pressure fluctuation to the refrigerant fluid.

  Therefore, even when the self-excited vibration once started is likely to stop due to fluctuations in the amount of heat generated by the heating element 12, the self-excited vibration can be stably performed.

(Fourth embodiment)
A cooler according to a fourth embodiment of the present invention will be described with reference to FIGS. Compared with the linear actuator 35 of the first embodiment, the linear actuator 35 of the cooler of the present embodiment can not only pressurize the expansion / contraction part 28 but also apply a tensile force in the direction of pulling the expansion / contraction part 28. Is different. The cooler of this embodiment differs in the control process of the control apparatus 30 compared with the cooler of the said 1st Embodiment. When it is determined that the self-excited vibration is attenuated, the cooler according to the present embodiment performs a process of operating the self-excited vibration promoting unit 32 according to the self-excited vibration and applying pressure fluctuation to the refrigerant fluid.

  FIG. 8 is a flowchart of the control device 30 of the present embodiment. FIG. 9 is a time chart for explaining the control processing shown in the flowchart of FIG. The time chart of FIG. 7 shows, in order from the top, (a) heating element temperature, (b) refrigerant pressure, (c) position of gas-liquid interface, (d) pressure applied by self-excited vibration promoting unit 32, (e) coil The detection electric power which generate | occur | produces in 35b is each shown.

  A control process of the control device 30 in FIG. 7 will be described. Here, it is assumed that the heating element 12 has already been activated and the gas-liquid interface 26 of the refrigerant is self-excited in the housing space 24.

  First, the displacement dx of the gas-liquid interface 26 is detected (S300). Specifically, the displacement dx of the gas-liquid interface 26 is detected based on the detection current of the coil 35b detected by the power supply 31.

Next, it is determined whether a predetermined value dx ₁ larger or not the displacement dx is predetermined in the gas-liquid interface 26. That is, it is determined whether or not the self-excited vibration is attenuated based on whether or not the displacement dx of the gas-liquid interface 26 is greater than a predetermined value dx ₁ (S402).

Here, not self-excited vibration is attenuated, when the displacement dx of the gas-liquid interface 26 becomes the predetermined value dx ₁ below, the determination of S402 returns NO, to S300.

Also, the self-excited vibration is attenuated, when the displacement dx of the gas-liquid interface 26 is greater than a predetermined value dx _1, the determination of S402 becomes YES, then the detection power VA generated in the coil 35b is smaller than 0 It is determined whether or not there is (S404). When the position of the gas-liquid interface 26 is displaced by the self-excited vibration, an electromotive force (detected power) is generated in the coil 35b so as to be synchronized with the displacement of the position of the gas-liquid interface 26. In the present embodiment, as shown in FIGS. 9C and 9E, when the position of the gas-liquid interface 26 is displaced toward the heating element 12, a positive electromotive force VA is generated in the coil 35b. That is, the phase of self-excited vibration can be detected by the electromotive force generated in the coil 35b.

Here, when the detected power VA is less than 0, the self-excited vibration promoting unit 32 is operated (S406). Specifically, as shown in FIG. 9D, the self-excited vibration promoting portion 32 is operated so that the pressure applied to the expansion / contraction portion 28 by the linear actuator 35 becomes the pressure _Pa1 . In addition, as for the applied pressure to the expansion-contraction part 28, let the direction which shrinks the expansion-contraction part 28 be a positive direction.

  If the detected power VA is 0 or more, it is determined whether or not the detected power VA is greater than 0 (S408).

Here, when the detected power VA is larger than 0, the self-excited vibration promoting unit 32 is operated (S410). Specifically, as shown in FIG. 9D, the self-excited vibration promoting unit 32 is operated so that the tensile force of the expansion / contraction unit 28 by the linear actuator 35 becomes the pressure −P _a1 .

  In the present embodiment, the same effect obtained from the configuration common to the first embodiment can be obtained as in the first embodiment.

  In addition, when determining that the self-excited vibration has attenuated, the control device 30 of the present embodiment identifies the phase of the self-excited vibration based on the displacement of the expansion / contraction portion 28 and synchronizes with the phase of the self-excited vibration. Thus, since the expansion / contraction part 28 controls the refrigerant fluid to change the pressure, the self-excited vibration can be stably performed.

(Fifth embodiment)
A cooler according to a fifth embodiment of the present invention will be described with reference to FIGS. 10 and 11. The configuration of the cooler of the present embodiment is the same as the cooler of the first embodiment. The cooler of this embodiment differs in the control process of the control apparatus 30 compared with the cooler of the said 1st Embodiment. When it is determined that the heating element 12 has stopped operating, the cooler 10 of the present embodiment performs processing to cool the heating element 12 more than usual.

  FIG. 10 is a flowchart of the control device 30 of the present embodiment. FIG. 11 is a time chart for explaining the control process shown in the flowchart of FIG. The time chart of FIG. 10 shows, in order from the top, (a) heating element temperature, (b) refrigerant pressure, (c) gas-liquid interface position, (d) self-excited vibration promoting unit 32 pressure, Excitation vibration promoting portions 32 are shown.

  Control processing of the control device 30 in FIG. 10 will be described. Here, it is assumed that the heating element 12 has already been activated and the gas-liquid interface 26 of the refrigerant is self-excited in the housing space 24.

  First, it is determined whether or not the heating element 12 has stopped operating (S500). Specifically, it is determined whether or not the heating element 12 has stopped operating based on an ON / OFF signal of the inverter included in the PCU signal. Here, when the heating element 12 has stopped operating, the determination in S100 is NO, and the self-excited vibration promoting unit 32 is set in the standby state. Specifically, the linear actuator 35 is controlled so as not to pressurize the expansion / contraction part 28 by the self-excited vibration promoting part 32.

When it is determined that the heating element 12 has stopped operating based on the ON / OFF signal of the inverter, the self-excited vibration promoting unit 32 is operated for a certain period of time t _a3 (S504).

Then, when it is determined that the predetermined period _ta3 has elapsed since the self-excited vibration promoting unit 32 is activated, the operation of the self-excited vibration promoting unit 32 is stopped (S506).

  In the present embodiment, the same effect obtained from the configuration common to the first embodiment can be obtained as in the first embodiment.

(Sixth embodiment)
A cooler according to a sixth embodiment of the present invention will be described with reference to FIGS. The cooler of this embodiment differs in the structure of the expansion-contraction part 28 and the self-excited vibration promotion part 32 compared with the cooler of each said embodiment.

  The cooler of each of the above embodiments includes a self-excited vibration promoting unit 32 having a linear actuator 35, and is configured to pressurize the expansion / contraction unit 28 by the linear actuator 35. On the other hand, the cooler according to the present embodiment includes a self-excited vibration promoting unit 32 having a compressor 50, and pressurizes the expansion / contraction unit 28 by the pressure of air generated by the compressor 50.

  As shown in FIG. 12, the extendable portion 28 is provided with a cover 25 that covers the expandable portion 28. The cover 25 is in close contact with the refrigerant container 14 at one end of the refrigerant container 14 on the expansion / contraction part 28 side. The cover 25 and the refrigerant container 14 form a sealed cover space 25a.

  Connected to the cover 25 are an air supply pipe 53 for supplying air to the cover space 25a and an air discharge pipe 54 for discharging air in the cover space 25a.

  The air supply pipe 53 is connected to a compressor 50 that compresses and discharges air taken from the atmosphere. The compressor 50 includes a compression mechanism that compresses air and an electric actuator that drives the compression mechanism. The air compressed by the compressor 50 is supplied into the cover space 25 a through the air supply pipe 53.

  An electromagnetic valve 51 that adjusts the pressure of air in the cover space 25 a is provided between the compressor 50 and the cover 25 in the air supply pipe 53. The electromagnetic valve 51 includes a valve body that adjusts an opening degree of an air flow path through which air flows in the air supply pipe 53 and an electric actuator that drives the valve body.

  A pressure sensor 55 is provided in the air supply pipe 53. The pressure sensor 55 detects the pressure of the air in the air supply pipe 53 and outputs a signal indicating the detected pressure to the control device 30. Note that the pressure detected by the pressure sensor 55 is the same as the pressure of air in the cover space 25a.

  One end side of the air discharge pipe 54 is connected to the cover 25, and the other end side is an open end 54a.

  Between the cover 25 and the open end 54a in the air discharge pipe 54, an electromagnetic valve 52 for adjusting the pressure of air in the cover space 25a is provided. The electromagnetic valve 52 includes a valve body that adjusts the opening degree of an air flow path through which air flows in the air discharge pipe 54 and an electric actuator that drives the valve body.

  Next, the operation of the self-excited vibration promoting unit 32 will be described. Here, it is assumed that the solenoid valve 51 and the solenoid valve 52 each close the air flow path.

  When the compressor 50 starts operation, compressed air is discharged from the compressor 50 to the air supply pipe 53. When the air flow path of the electromagnetic valve 51 is opened by an instruction from the control device 30, the air compressed by the compressor 50 is supplied into the cover 25 through the air supply pipe 53. And the air pressure in the cover space 25a becomes high gradually.

  Thus, when the air pressure in the cover space 25a increases, one end of the refrigerant container 14 on the side of the expansion / contraction part 28 is pressurized and the expansion / contraction part 28 contracts. And the pressure of a refrigerant fluid rises because the expansion-contraction part 28 shrinks.

  Further, when the air flow path of the electromagnetic valve 51 is closed and the air flow path of the electromagnetic valve 52 is opened, the air in the cover 25 passes through the air flow path of the electromagnetic valve 51 and is released into the atmosphere from the open end 54a. . And the pressure in the cover space 25a becomes equivalent to atmospheric pressure, and the pressure of the refrigerant fluid decreases.

  Thus, when the pressure in the cover space 25a becomes equal to the atmospheric pressure, one end of the refrigerant container 14 on the side of the expansion / contraction part 28 is not pressurized and the expansion / contraction part 28 returns to the state before being pressurized.

  Next, with reference to FIG. 13, the control process of the control apparatus 30 of this embodiment is demonstrated. FIG. 13 is a flowchart of the control device 30 of the present embodiment. The control device 30 periodically performs the process shown in FIG.

First, the compressor 50 is operated, and control is performed to open the electromagnetic valve 51 and close the electromagnetic valve 52 (S600). Specifically, as the air pressure P in the cover space 25a is higher predetermined pressure P ₂ lower than the atmospheric pressure, and controls the rotational speed and the electromagnetic valve 51 of the compressor 50.

Thus, the air pressure P in the cover space 25a is a predetermined pressure _{P 2.} And the expansion-contraction part 28 is pressurized by the air pressure P in the cover space 25a, and shrinks. Furthermore, the stretchable portion 28 takes pressure of a predetermined pressure P _2, the refrigerant pressure is high pressure P _sat2 next than before, the refrigerant boiling point higher.

Next, the solenoid valve 51 is controlled to be closed while the solenoid valve 52 is closed (S602). Accordingly, the air pressure P in the cover space 25a is maintained at a predetermined pressure P _2.

  Next, the air pressure P in the cover space 25a is detected (S604). The air pressure P in the cover space 25 a can be specified based on a signal output from the pressure sensor 55.

Next, it is determined whether or not the air pressure P in the cover space 25a is higher than a predetermined pressure P ₂ + α higher than the atmospheric pressure (S606). Thus, whether or not the refrigerant has boiled is determined based on whether or not the air pressure P in the cover space 25a is higher than the predetermined pressure P ₂ + α higher than the atmospheric pressure.

Here, when the air pressure P in the cover space 25a is equal to or lower than the predetermined pressure P ₂ + α higher than the atmospheric pressure, the determination in S606 is NO and the process returns to S604.

Further, when the refrigerant boils and the air pressure P in the cover space 25a becomes higher than the predetermined pressure P ₂ + α higher than the atmospheric pressure, the determination in S606 becomes YES, and then the electromagnetic valve 51 remains closed. Then, the electromagnetic valve 52 is opened (S608).

Thereby, the air in the cover 25 passes through the air discharge pipe 54 and is discharged into the atmosphere from the open end 54a, and the air pressure P in the cover space 25a becomes the same as the atmospheric pressure P _air . Further, the pressure applied to the expansion / contraction part 28 by the self-excited vibration promoting part 32 becomes 0, the refrigerant boiling point rapidly decreases to the value before pressurization, and the refrigerant boils rapidly.

  In the present embodiment, the same effect obtained from the configuration common to the first embodiment can be obtained as in the first embodiment.

(Seventh embodiment)
A cooler according to a seventh embodiment of the present invention will be described with reference to FIG. The configuration of the cooler of the present embodiment is the same as that of the sixth embodiment. The cooler of this embodiment differs in the control process of the control apparatus 30 compared with the cooler of the said 6th Embodiment.

  Next, with reference to FIG. 14, the control process of the control apparatus 30 of this embodiment is demonstrated. FIG. 14 is a flowchart of the control device 30 of the present embodiment. The control device 30 periodically performs the process shown in FIG.

  First, the air pressure P in the cover space 25a is detected (S700). The air pressure P in the cover space 25 a can be specified based on a signal output from the pressure sensor 55.

Next, a pressure amplitude gradient dP is calculated (S702). FIG. 15 shows the amplitude of the refrigerant pressure when the self-excited vibration is attenuated. The pressure amplitude gradient dP can be calculated as dP = (P ₁ −P ₂ ) / dt ₁ , where P ₁ is the pressure amplitude at a certain time and P ₂ is the pressure amplitude after the lapse of the predetermined period dt _1. .

  Next, it is determined whether or not the pressure amplitude gradient dP is larger than a predetermined set constant (S704). If the self-excited vibration is not attenuated and the pressure amplitude gradient dP is greater than or equal to the set constant, the determination in S704 is NO and the process returns to S700.

If the self-excited vibration is attenuated and the pressure amplitude gradient dP is smaller than the set constant, the determination in S704 is YES, and then the electromagnetic valve 52 is opened while the electromagnetic valve 51 is closed (S706). Thereby, the air pressure P in the cover space 25a becomes the same as the atmospheric pressure P _air .

Next, the compressor 50 is operated, and the solenoid valve 51 is opened and the solenoid valve 52 is closed. Specifically, as the air pressure P in the cover space 25a is higher predetermined pressure P ₁ than the atmospheric pressure, and controls the rotational speed and the electromagnetic valve 51 of the compressor 50.

Thus, the air pressure P in the cover space 25a is a predetermined pressure _{P 1.} And the expansion-contraction part 28 is pressurized by the air pressure P in the cover space 25a, and shrinks. Furthermore, the stretchable portion 28 takes pressure of a predetermined pressure P _2, the refrigerant pressure becomes higher pressure P _sat2 than before, the refrigerant boiling point higher.

  In the present embodiment, the same effect obtained from the configuration common to the first embodiment can be obtained as in the first embodiment.

(Other embodiments)
(1) In each of the above embodiments, the inverter power module is cooled as the heating element 12, but the heating element 12 is not limited to the inverter power module.

  (2) In each of the above embodiments, in S104, S200, and S300, the self-excited vibration of the refrigerant fluid is attenuated or stopped based on the displacement dx of the gas-liquid interface 26 that correlates with the displacement of the expansion / contraction part 28. When the determination is made, the expansion / contraction part 28 is controlled to give a pressure fluctuation to the refrigerant fluid.

  On the other hand, when it is determined that the self-excited vibration of the refrigerant fluid is attenuated or stopped based on the pressure of the refrigerant fluid that correlates with the displacement of the expansion / contraction part 28, the expansion / contraction part 28 is set so as to give a pressure fluctuation to the refrigerant fluid. You may comprise so that it may control.

  In addition, when it is determined that the self-excited vibration of the refrigerant fluid is attenuated or stopped based on both the displacement dx of the gas-liquid interface 26 and the pressure of the refrigerant fluid, the expansion / contraction part 28 is provided so as to give a pressure fluctuation to the refrigerant fluid. You may comprise so that it may control.

  (3) In the first to fourth embodiments, the displacement of the expansion / contraction part 28 is detected based on the electromotive force generated in the coil 35b that displaces the position of the expansion / contraction part 28. It can also comprise so that the displacement of the expansion-contraction part 28 may be detected with a method.

  (4) In the fourth embodiment, the self-excited vibration promoting unit applies pressure fluctuation to the refrigerant fluid in synchronization with the phase of the self-excited vibration specified based on the displacement of the movable unit detected by the detecting unit. Although configured, for example, the refrigerant fluid may be configured to vary in pressure in synchronization with the phase of self-excited vibration specified based on the pressure of the refrigerant fluid.

  (5) In each of the above embodiments, when the self-excited vibration promoting unit determines that the self-excited vibration of the refrigerant fluid is damped based on the displacement of the movable unit detected by the detecting unit, the self-excited vibration promoting unit adds the refrigerant fluid. The position of the movable part was controlled so as to press. On the other hand, when it is determined that the self-excited vibration of the refrigerant fluid has stopped based on the displacement of the movable part detected by the detection unit, the position of the movable part may be controlled to pressurize the refrigerant fluid. .

  (6) In each of the above-described embodiments, the heating element 12 is accommodated in the heating unit tubular space 221 and thus directly contacts the refrigerant. However, if the refrigerant of the heating unit 141 can be boiled by the heat of the heating element 12. The heating element 12 does not need to be in direct contact with the refrigerant, and the arrangement position of the heating element 12 is not limited. For example, you may comprise so that the heat generating body 12 may be affixed on the outer wall of the heating part 141, and may be cooled indirectly.

  In addition, this invention is not limited to above-described embodiment, In the range described in the claim, it can change suitably. Further, the above embodiments are not irrelevant to each other, and can be combined as appropriate unless the combination is clearly impossible.

  The correspondence relationship between the configuration of the above embodiment and the configuration of the claims will be described. S104, S300, S604, and S700 are detection units that detect at least one of the displacement of the expansion / contraction unit 28 and the pressure of the refrigerant fluid. Equivalent to.

DESCRIPTION OF SYMBOLS 10 Cooler 12 Heating element 141 Heating part 142 Cooling part 26 Gas-liquid interface 28 Stretching part 32 Self-excited vibration promoting part 35 Linear actuator

Claims (9)

A heating unit (141) that heats and vaporizes a part of the refrigerant fluid enclosed in the tubular housing space by heat from the heating element (12);
A cooling unit (142) for cooling and liquefying the refrigerant fluid vaporized in the heating unit,
By repeating vaporization of the refrigerant fluid by the heating unit and liquefaction of the refrigerant fluid by the cooling unit, the refrigerant fluid is self-excited in the housing space, and the heating element is cooled along with the self-excited vibration. A cooler that
A movable portion (28) that is displaced in the axial direction of the housing space and applies pressure fluctuation to the refrigerant fluid;
A detection unit (S104, S300, S604, S700) for detecting at least one of the displacement of the movable unit and the pressure of the refrigerant fluid;
A self-excited vibration accelerating unit (32) that provides pressure fluctuation to the refrigerant fluid so as to promote the self-excited oscillation of the refrigerant fluid based on at least one of the displacement of the movable part and the pressure of the refrigerant fluid detected by the detection unit. ) and, with a,
The detection unit has a coil (35b) for displacing the position of the movable unit,
A cooler that detects displacement of the movable part based on an electromotive force generated in the coil . A heating unit (141) that heats and vaporizes a part of the refrigerant fluid enclosed in the tubular housing space by heat from the heating element (12);
A cooling unit (142) for cooling and liquefying the refrigerant fluid vaporized in the heating unit,
By repeating vaporization of the refrigerant fluid by the heating unit and liquefaction of the refrigerant fluid by the cooling unit, the refrigerant fluid is self-excited in the housing space, and the heating element is cooled along with the self-excited vibration. A cooler that
A movable portion (28) that is displaced in the axial direction of the housing space and applies pressure fluctuation to the refrigerant fluid;
A detection unit (S104, S300, S604, S700) for detecting at least one of the displacement of the movable unit and the pressure of the refrigerant fluid;
A self-excited vibration accelerating unit (32) that provides pressure fluctuation to the refrigerant fluid so as to promote the self-excited oscillation of the refrigerant fluid based on at least one of the displacement of the movable part and the pressure of the refrigerant fluid detected by the detection unit. ) and, with a,
The detection unit detects a displacement of the movable unit,
The self-excited vibration promoting unit is a cooler that applies pressure fluctuation to the refrigerant fluid when it is determined that the displacement of the movable unit detected by the detection unit is greater than a predetermined value . A heating unit (141) that heats and vaporizes a part of the refrigerant fluid enclosed in the tubular housing space by heat from the heating element (12);
A cooling unit (142) for cooling and liquefying the refrigerant fluid vaporized in the heating unit,
By repeating vaporization of the refrigerant fluid by the heating unit and liquefaction of the refrigerant fluid by the cooling unit, the refrigerant fluid is self-excited in the housing space, and the heating element is cooled along with the self-excited vibration. A cooler that
A movable portion (28) that is displaced in the axial direction of the housing space and applies pressure fluctuation to the refrigerant fluid;
A detection unit (S104, S300, S604, S700) for detecting at least one of the displacement of the movable unit and the pressure of the refrigerant fluid;
A self-excited vibration accelerating unit (32) that provides pressure fluctuation to the refrigerant fluid so as to promote the self-excited oscillation of the refrigerant fluid based on at least one of the displacement of the movable part and the pressure of the refrigerant fluid detected by the detection unit. ) and, with a,
The detection unit detects a displacement amount per unit time of the movable unit,
The self-excited vibration promoting unit is a cooler that applies a pressure fluctuation to the refrigerant fluid when it is determined that a displacement amount per unit time of the movable unit detected by the detection unit is larger than a predetermined value . A heating unit (141) that heats and vaporizes a part of the refrigerant fluid enclosed in the tubular housing space by heat from the heating element (12);
A cooling unit (142) for cooling and liquefying the refrigerant fluid vaporized in the heating unit,
By repeating vaporization of the refrigerant fluid by the heating unit and liquefaction of the refrigerant fluid by the cooling unit, the refrigerant fluid is self-excited in the housing space, and the heating element is cooled along with the self-excited vibration. A cooler that
A movable portion (28) that is displaced in the axial direction of the housing space and applies pressure fluctuation to the refrigerant fluid;
A detection unit (S104, S300, S604, S700) for detecting at least one of the displacement of the movable unit and the pressure of the refrigerant fluid;
A self-excited vibration accelerating unit (32) that provides pressure fluctuation to the refrigerant fluid so as to promote the self-excited oscillation of the refrigerant fluid based on at least one of the displacement of the movable part and the pressure of the refrigerant fluid detected by the detection unit. ) and, with a,
The detection unit detects the amount of change in the pressure of the refrigerant fluid,
The self-excited vibration promoting unit is a cooler that applies pressure fluctuation to the refrigerant fluid when it is determined that the amount of change in the pressure of the refrigerant fluid detected by the detection unit is greater than a predetermined value . A heating unit (141) that heats and vaporizes a part of the refrigerant fluid enclosed in the tubular housing space by heat from the heating element (12);
A cooling unit (142) for cooling and liquefying the refrigerant fluid vaporized in the heating unit,
By repeating vaporization of the refrigerant fluid by the heating unit and liquefaction of the refrigerant fluid by the cooling unit, the refrigerant fluid is self-excited in the housing space, and the heating element is cooled along with the self-excited vibration. A cooler that
A movable portion (28) that is displaced in the axial direction of the housing space and applies pressure fluctuation to the refrigerant fluid;
A detection unit (S104, S300, S604, S700) for detecting at least one of the displacement of the movable unit and the pressure of the refrigerant fluid;
A self-excited vibration accelerating unit (32) that provides pressure fluctuation to the refrigerant fluid so as to promote the self-excited oscillation of the refrigerant fluid based on at least one of the displacement of the movable part and the pressure of the refrigerant fluid detected by the detection unit. ) and, with a,
The detection unit detects a change amount per unit time of the pressure of the refrigerant fluid,
The self-excited vibration promoting unit gives pressure fluctuation to the refrigerant fluid when it is determined that the amount of change in the pressure of the refrigerant fluid detected by the detection unit is greater than a predetermined value. The cooler described in. A heating unit (141) that heats and vaporizes a part of the refrigerant fluid enclosed in the tubular housing space by heat from the heating element (12);
A cooling unit (142) for cooling and liquefying the refrigerant fluid vaporized in the heating unit,
By repeating vaporization of the refrigerant fluid by the heating unit and liquefaction of the refrigerant fluid by the cooling unit, the refrigerant fluid is self-excited in the housing space, and the heating element is cooled along with the self-excited vibration. A cooler that
A movable portion (28) that is displaced in the axial direction of the housing space and applies pressure fluctuation to the refrigerant fluid;
A detection unit (S104, S300, S604, S700) for detecting at least one of the displacement of the movable unit and the pressure of the refrigerant fluid;
A self-excited vibration accelerating unit (32) that provides pressure fluctuation to the refrigerant fluid so as to promote the self-excited oscillation of the refrigerant fluid based on at least one of the displacement of the movable part and the pressure of the refrigerant fluid detected by the detection unit. ) and, with a,
The self-excited vibration promoting unit is configured to pressurize the refrigerant fluid in synchronization with a phase of the self-excited vibration specified based on at least one of the displacement of the movable unit detected by the detecting unit and the pressure of the refrigerant fluid. A cooler that gives fluctuations . A heating unit (141) that heats and vaporizes a part of the refrigerant fluid enclosed in the tubular housing space by heat from the heating element (12);
A cooling unit (142) for cooling and liquefying the refrigerant fluid vaporized in the heating unit,
By repeating vaporization of the refrigerant fluid by the heating unit and liquefaction of the refrigerant fluid by the cooling unit, the refrigerant fluid is self-excited in the housing space, and the heating element is cooled along with the self-excited vibration. A cooler that
A movable portion (28) that is displaced in the axial direction of the housing space and applies pressure fluctuation to the refrigerant fluid;
A detection unit (S104, S300, S604, S700) for detecting at least one of the displacement of the movable unit and the pressure of the refrigerant fluid;
A self-excited vibration accelerating unit (32) that provides pressure fluctuation to the refrigerant fluid so as to promote the self-excited oscillation of the refrigerant fluid based on at least one of the displacement of the movable part and the pressure of the refrigerant fluid detected by the detection unit. ) and, with a,
The self-excited vibration promoting unit is a cooler that controls the position of the movable unit to increase the pressure of the refrigerant fluid when it is determined that the heating element has started to operate based on an external signal . The self-excited vibration promoting unit determines that the self-excited vibration of the refrigerant fluid is attenuated or stopped based on at least one of the displacement of the movable unit and the pressure of the refrigerant fluid detected by the detection unit. In this case, the cooler according to any one of claims 1 to 6 , wherein the position of the movable portion is controlled so as to pressurize the refrigerant fluid. The self-excited vibration promoting unit controls the position of the movable unit so as to increase the pressure of the refrigerant fluid, and then based on at least one of the displacement of the movable unit and the pressure of the refrigerant fluid detected by the detection unit. The cooler according to claim 7 or 8 , wherein the position of the movable part is controlled so as to reduce the pressure of the refrigerant fluid.

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