JP3630993B2 - Stirling cooling device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a Stirling cooling apparatus, and more particularly to a Stirling refrigerator constituting the Stirling cooling apparatus.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, systems that use chlorofluorocarbon as a refrigerant are known as refrigeration apparatuses for commercial and household refrigeration equipment. Refrigeration equipment using HCFCs and HFCs is known for recent CFC regulations against the background of global environmental problems, but further regulations on the use of CFCs, including specific CFCs and alternative CFCs, will be required in the future. In the direction. Also, conventional cooling devices using chlorofluorocarbon as a refrigerant have a narrow operating temperature range due to the characteristics of the system. In particular, with the recent technological development in each industrial field, there is a need for the development of other types of cooling devices. It is important.
[0003]
Therefore, without using chlorofluorocarbon, the operating temperature is wider than that of conventional cooling devices.For example, low-temperature liquid circulators, low-temperature devices such as refrigerators, refrigerators, throw-in coolers, etc. Compact and applicable to all industrial refrigeration equipment such as incubators, thermostats, heat shock test equipment, freeze dryers, temperature characteristics test equipment, blood / cell storage equipment, cold coolers, and other various refrigeration equipment. In addition, a Stirling cooling device composed of a Stirling refrigerator that has a high coefficient of performance and good energy efficiency has attracted attention.
[0004]
As a Stirling cooling device, a Stirling refrigerator that encloses a working gas, has a cooling head and a heat exchanger for heat dissipation, a cold refrigerant line through which a cold refrigerant cooled in the cooling head flows, and a cold refrigerant line The refrigeration refrigerant inlet plug and the outlet plug provided at the other end, and the refrigeration refrigerant outlet plug and inlet plug are detachably connected to the refrigeration refrigerant conduit of the refrigeration equipment. There is known a configuration in which a cooling refrigerant circulation pipe is formed between a Stirling refrigerator and the cold energy utilization device so as to convey cold energy to the cold energy utilization device.
[0005]
In Stirling refrigerators, the refrigerator is equipped with a temperature detector to monitor the temperature state of the water-cooled part of the refrigerator, and if the refrigerator is abnormal and the temperature rises, the refrigerator is stopped to protect it. I was planning. Further, since the temperature rises as the pressure of the water cooling part of the refrigerator rises, it is possible to detect the pressure with respect to the temperature with a temperature detector. However, since the temperature detector has poor temperature followability and may be disconnected, it takes a little time to detect the temperature because it is used in a fail-safe manner.
[0006]
[Problems to be solved by the invention]
For this reason, abnormalities in the refrigerator and sudden pressure rises in the water-cooled part cannot be handled by indirect detection, as detected by a temperature detector, and a hot water hose is welded like a refrigerant circuit of an air conditioner. Therefore, there is a possibility that an inconvenient situation such as disconnection of the hose due to an increase in water pressure may occur. The present invention provides a Stirling refrigerator capable of directly detecting pressure and preventing inconveniences such as disconnection of a hose even when an abnormality of the refrigerator such as a water pump failure occurs and a sudden pressure rise in the water cooling section occurs. For the purpose.
[0007]
[Means for Solving the Problems]
In order to solve the above problems, a Stirling cooling apparatus according to claim 1 of the present invention includes a Stirling refrigerator that encloses a working gas and has a cooling head and a heat exchanger for heat dissipation, and cooling heat that is cooled in the cooling head. A cold refrigerant line through which the refrigerant flows, an inlet plug of the cold refrigerant provided at one end of the cold refrigerant line, and an outlet plug provided at the other end of the refrigerant line; A refrigeration refrigerant pipe is connected to the refrigeration refrigerant pipe of the refrigeration equipment so that the refrigeration refrigerant circulation pipe is formed between the Stirling refrigerator and the refrigeration equipment, and the refrigeration equipment is conveyed with the refrigeration heat. In the Stirling cooling device, the Stirling refrigerator is provided with a temperature detector, and the water pressure is detected in the cooling water circulation line formed by connecting the heat-dissipating heat exchanger and the heat-dissipating device in an annular shape. The provided, has a structure for controlling the operation of the Stirling refrigerator by the output of the pressure detector and the temperature detector.
[0008]
In this way, a Stirling refrigerator that can directly detect the pressure and prevent inconveniences such as disconnection of the hose used in the cooling water circulation path even if an abnormality of the refrigerator such as a water pump failure occurs and a sudden pressure rise in the water cooling section occurs. Can be realized.
[0009]
A Stirling cooling apparatus according to a second aspect of the present invention includes a Stirling refrigerator that includes a working gas and has a cooling head and a heat exchanger for heat dissipation, and a cold refrigerant channel through which a cold refrigerant cooled in the cooling head flows. And a cold refrigerant inlet plug provided at one end of the cold refrigerant conduit and an outlet plug provided at the other end, and the cold refrigerant outlet plug and inlet plug are connected to a cold refrigerant pipe of a cold energy utilization device. In a Stirling cooling apparatus comprising a refrigeration refrigerant circulation line formed between the Stirling refrigerator and the cold energy utilization device by transferring the cold heat to the cold energy utilization device by being connected detachably. The Stirling refrigerator is provided with a temperature detector, and a water pressure detector is provided in a cooling water circulation line formed by connecting the heat dissipation heat exchanger and the heat dissipation device in an annular shape. There was configured to stop the operation of the Stirling refrigerating machine when the detection value of the water pressure detector exceeds a predetermined value.
[0010]
In this way, the temperature detector monitors the temperature state of the water-cooling part of the refrigerator, and when the abnormality occurs in the refrigerator and the temperature rises, the operation of the refrigerator is stopped and protected. Even if a machine abnormality occurs and a sudden pressure rise in the water cooling section occurs, the pressure can be detected directly, and inconveniences such as disconnection of the hose can be reliably and quickly prevented.
[0011]
A Stirling cooling apparatus according to a third aspect of the present invention includes a Stirling refrigerator that includes a working gas and has a cooling head and a heat exchanger for heat dissipation, and a cold refrigerant pipe through which a cold refrigerant cooled in the cooling head flows. And a cold refrigerant inlet plug provided at one end of the cold refrigerant conduit and an outlet plug provided at the other end, and the cold refrigerant outlet plug and inlet plug are connected to a cold refrigerant pipe of a cold energy utilization device. In a Stirling cooling apparatus comprising a refrigeration refrigerant circulation line formed between the Stirling refrigerator and the cold energy utilization device by transferring the cold heat to the cold energy utilization device by being connected detachably. A water pressure detector is provided in a cooling water circulation line formed by connecting a temperature detector to the Stirling refrigerator and connecting the heat-dissipating heat exchanger and the heat-dissipating device in an annular shape. Detection value stops the operation of the Stirling refrigerating machine when the predetermined value or more, was resumed configure operation of the Stirling refrigerator When equal to or less than a predetermined value.
[0012]
In this way, the Stirling refrigerator operation was stopped when the detected value of the water pressure detector was equal to or higher than the predetermined value, and the Stirling refrigerator operation was restarted when the detected value was lower than the predetermined value. If there is, the operation of the refrigerator is automatically continued, and if these operations are repeated several times, the operation of the Stirling refrigerator can be stopped and the operation for removing the failure can be efficiently performed. .
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings based on examples. FIG. 1 is a diagram for explaining the outline of the Stirling cooling apparatus of the present invention. The Stirling cooling device 1 is configured by arranging a Stirling refrigerator 3 of the present invention in a box-shaped case 2.
[0014]
The Stirling refrigerator 3 has a cooling head 4, and the cooling head 4 circulates a cooling / refrigerating refrigerant pipe (a refrigerant for conveying the cooling heat generated in the Stirling refrigerator 3 to a heat utilization device such as a freezer). A path 5 is connected, and both ends of the cold refrigerant line 5 penetrate the case 2, and an inlet plug 6 and an outlet plug 7 for the cold refrigerant are provided outside the case 2.
[0015]
When the Stirling cooling apparatus 1 is used, an outlet end 9 and an inlet end 10 of a cooling refrigerant pipe of a cooling / heating equipment 8 such as a freezer are detachably connected to the inlet plug 6 and the outlet plug 7. In the middle of the cold-heat refrigerant pipe 5, a cold-heat refrigerant pump P <b> 2 is disposed, and the cold-heat refrigerant is circulated between the cooling head 4 of the schooling refrigerator 3 and the cold-heat utilization device 8.
[0016]
In addition to the freezer, the cold energy utilization device 8 includes a refrigerator, a throw-in cooler, a low-temperature liquid circulator, a low-temperature fence heater for various temperature characteristic tests, a thermostatic bath, a heat shock test device, a freeze dryer, a cold cooler, etc. The Stirling cooling device 1 can be used by connecting these cold energy utilization devices to the inlet plug 6 and the outlet plug 7.
[0017]
In FIG. 2, the Stirling refrigeration apparatus 3 will be described in detail. The housing 11 of the Stirling refrigerator 3 of the present invention is formed of a casting, and a shilling 12 is formed on the top of the housing 11. The housing 11 is partitioned into a motor chamber 14 and a crank chamber 15 by a partition wall 13. A motor 16 capable of rotating in the forward and reverse directions is reciprocated in the motor chamber 14, and the rotation operation of the motor 16 is reciprocated in the crank chamber 15. A rotary reciprocating conversion mechanism portion 17 for converting motion is provided. The opening 18 of the motor chamber and the opening 19 of the crank chamber are closed by lids 20 and 21, respectively, and the inside of the housing 11 is held by a semi-sealed bear.
[0018]
In the housing 11, a crank shaft 23 that penetrates the partition wall 13 and is pivotally supported by the housing wall, the partition wall 13, and the bearing portions 22 of the lids 20 and 21 is rotatably disposed. The motor 16 includes a stator 24a and a rotor 24b that is rotatably arranged on the inner peripheral side of the stator, and a crankshaft 23 is fixed to the center of the rotor 24b.
[0019]
The rotary reciprocating conversion mechanism 17 includes a crank portion 25 of a crankshaft 23 extending into the crank chamber 15, connecting rods 26 and 27 connected to the crank portion 25, and a cross attached to the tips of the connecting rods 26 and 27. The guide heads 28 and 29 are configured to function as drive means for the Stirling refrigerator 3.
[0020]
The cross guide heads 28 and 29 are disposed so as to reciprocate within the cross guide liners 30 and 31 provided on the inner wall of the shilling 12 of the housing 11. The crank portion is formed with a phase difference so that the crank 25b moves ahead of the crank 25a when the motor 16 rotates forward. As this phase difference, a phase difference of 90 degrees is generally adopted.
[0021]
A compression cylinder 32 and an expansion shilling 33 located slightly above the compression shilling 32 are disposed on the upper portion of the crank chamber 15 of the housing 11 of the Stirling refrigerator 3. The housing 11 including the compression shilling 32 and the expansion shilling 33 is filled with, for example, helium, hydrogen, nitrogen or the like as a working gas. The compression cylinder 32 has a compression cylinder block 34 fixed to the housing 11 with bolts or the like, and a compression piston 36 provided with a piston ring 35 reciprocates and slides in the space of the compression cylinder block 34. The upper portion (compression space) is a high-temperature chamber 37, and the working gas therein is compressed and becomes high temperature.
[0022]
One end of the compression piston rod 38 is fixed to the compression piston 36, the other end extends through an oil seal 39, and is rotatably connected to the cross guide head by a pin. Since the reciprocating compression piston 36 reverses the sliding direction at the top dead center and the bottom dead center, the speed becomes zero, and the speed is slow near the top dead center and the bottom dead center, and the amount of change in volume per unit time is also large. Small, maximum speed at each intermediate point when moving from bottom dead center to top dead center and top dead center to bottom dead center, and maximum volume change due to piston movement per unit time .
[0023]
On the other hand, the expansion shilling 33 has an expansion shilling block 40 fixed to the upper part of the compression shilling 32 with a bolt or the like, and an expansion piston 42 provided with a piston ring 35 reciprocally slides in the space of the expansion cylinder block 40. And the upper part (expansion space) of this space is the low temperature chamber 41, and the working gas in this expand | swells and becomes low temperature. One end of an expansion piston rod 43 is fixed to the expansion piston 42, and the other end of the expansion piston rod 43 extends through an oil seal 44 and is connected to the cross guide head 29. The expansion piston 42 moves ahead of the compression piston 36 by a phase of 90 degrees.
[0024]
From the bottom of the drawing, the expansion shilling block 40 is provided with a manifold 45 through which working gas flows in and out of the compression space of the compression shilling 32, and further, a heat exchanger 46 for heat dissipation, a regenerator 47, and a high temperature chamber. A passage 48 to 37 is arranged in an annular shape in sequential communication with each other. Near the upper end of the compression cylinder block 34, a communication hole 49 is formed to communicate the high temperature chamber 37 and the manifold 45, whereby the high temperature chamber 37 (compression space) and the low temperature chamber 41 (expansion space) communicate with each other. The holes 49, the manifold 45, the heat radiating heat exchanger 46, the regenerator 47, and the passage 48 are sequentially communicated with each other. The passage 48 may be a cooler by arranging a heat exchanger in this portion.
[0025]
The heat dissipating heat exchanger 46 is an annular type heat exchanger, for example, a large number of tubes through which a working gas flows in an annular heat exchanging chamber is provided in the axial direction to allow cooling water to flow into the heat exchanging chamber. Shell-and-tube heat exchanger that cools the working gas, or heat exchanger that cools the working gas by disposing an annular jacket around the annular working gas flow path and flowing cooling water through the jacket Etc. The heat-dissipating heat exchanger 46 is provided with a protective temperature detector 60 that detects the temperature of the water-cooled part.
[0026]
The heat radiating heat exchanger 46 is connected to the heat radiating device 55 through the cooling water circulation pipe 54 and the cooling water pump P1, and circulates the cooling water. Cooling water heated and exchanged by the heat radiating heat exchanger 46 is cooled by a cooling fan of the radiator. Further, a water pressure detector 50 for detecting the water pressure is installed in the cooling water circulation pipe 54. The cooling water circulation pipe is connected to a branch pipe, and a water reservoir tank 57 is connected to the pipe via a reservoir valve 56. In addition, an air vent 58 and a drain valve 59 are connected to the radiator.
[0027]
The heat-dissipating heat exchanger 46 may not be water-cooled as described above, but may have an air-cooled structure in which air-cooling fins are formed on the outer wall surface of the working gas flow path of the expansion cylinder block 40. A cooling head 4 is formed on the upper portion of the expansion shilling block 40.
[0028]
As already described, the cooling head 4 is connected to the cold energy utilization device 8 via the cold refrigerant channel 5 and the cold refrigerant pump P2, and circulates the cold refrigerant. A suction tank 65 is disposed in the cold heat refrigerant pipe 5. A cold / hot refrigerant reservoir tank 67 is connected to the suction tank 65 via a reservoir valve 66. A drain valve 68 is connected to the suction tank 65.
An air vent 69 is connected to the cold / hot refrigerant pipe 5. As the cold refrigerant, ethyl alcohol, HFE, PFC, nitrogen, helium, or the like is used.
[0029]
This Stirling refrigerator is a Stirling refrigerator having a large refrigerating capacity by using two pistons of a compression cylinder 32 and an expansion cylinder 33 to increase the volume fluctuation of the space filled with the working gas in the Stirling refrigerator 3. 3 can be provided.
[0030]
If the Stirling refrigerator 3 of the present invention is provided with a temperature control device and a temperature detector is provided on the cold energy utilization device 8 side, the temperature control of the cold energy utilization device 8 can be performed from the schooling refrigerator 3 side. That is, in FIG. 3, a temperature detector is disposed in the cold energy utilization device 8, and a temperature control device that allows temperature setting by a temperature setting panel is disposed in the Stirling refrigerator. In the comparison circuit in the temperature control circuit constituting the temperature control device, the temperature signal of the cold energy utilization device 8 detected by the temperature detector is compared with the set temperature, and the allowable temperature range centered on the set temperature is obtained. In accordance with the result, the motor 16 of the Stirling refrigerator 3 is controlled to be turned on / off or controlled by an inverter, or the motor 16 is rotated in the reverse direction to maintain the temperature within the allowable temperature range. Can be performed.
[0031]
Next, the operation of the Stirling refrigerator 3 of the above embodiment of the present invention will be described. The crankshaft 23 is rotated in the forward direction by the motor 16, and the cranks 25a and 25b in the crank chamber 15 are rotated 90 degrees out of phase. The cross guide heads 28 and 29 attached to the tips of the connecting rods 26 and 27 are reciprocated in the cross guide liners 30 and 31 via connecting rods 26 and 27 rotatably connected to the crank portions 25a and 25b. Slide. The compression piston 36 and the expansion piston 42 connected to the cross guide heads 28 and 29 via the compression piston rod 38 and the expansion piston rod 43 reciprocate with a phase difference of 90 degrees.
[0032]
While the expansion piston 42 moves 90 degrees ahead and slowly moves near the top dead center, the compression piston 36 moves rapidly near the middle toward the top dead center to perform the compression operation of the working gas. The compressed working gas flows into the heat radiating heat exchanger 46 through the communication hole 49 and the manifold 45. The working gas radiated to the cooling water in the heat radiating heat exchanger 46 is cooled by the regenerator 47 and flows into the low temperature chamber 41 (expansion space) through the passage 48.
[0033]
When the compression piston 36 is slowly moving near the top dead center, the expansion piston 42 abruptly moves toward the bottom dead center, and the working gas flowing into the low temperature chamber 41 (expansion space) rapidly expands to generate cold heat. To do. As a result, the top of the expansion cylinder block 40 of the cooling head 4 that surrounds the expansion space is cooled to a low temperature.
[0034]
In the cooling head 4, the cold refrigerant circulating in the cold refrigerant line is cooled. When the expansion piston 42 moves from the bottom dead center to the top dead center, the compression piston 36 is moving from the intermediate position toward the bottom dead center, and the working gas flows from the expansion space through the passage to the regenerator 47 and the cold heat of the working gas. Is stored in the regenerator 47. The cold energy stored in the regenerator 47 is reused to re-cool the working gas sent from the high temperature chamber 37 through the heat dissipation heat exchanger 46 as described above.
[0035]
Then, the refrigeration refrigerant cooled in the cooling head 4 is sent from the refrigeration refrigerant pipe 5 and the refrigeration refrigerant outlet plug 7 to the refrigeration refrigerant pipe in the refrigeration equipment 8 such as a freezer, for example. Performs freezing or cooling. In the cold energy utilization device 8, the cold refrigerant absorbs heat and cools, and is sent from the cold refrigerant pipe to the cold refrigerant inlet plug 6 of the cooling device, passes through the cold refrigerant line 5, and returns to the cooling head 4. And cooled there.
[0036]
In this way, the cold refrigerant circulates between the cooling head 4 of the Stirling refrigerator 3 and the cold energy utilization device 8, and the cold refrigerant is cooled by the Stirling refrigerator 3, and this cold refrigerant has a cooling action in the cold energy utilization device 8. To do. Thereafter, the same cycle is repeated.
[0037]
The cooling water heat-exchanged by the heat radiating heat exchanger 46 flows from the cooling water circulation pipe 54 to the heat radiating device 55, where it is cooled by the cooling fan and circulates again to the heat radiating heat exchanger 46.
[0038]
Moreover, when the cold energy utilization apparatus 8 is a cooling thermostat, the cooling operation by reverse rotation of the motor 16 can be used. That is, the temperature of the thermostatic chamber is measured while performing the normal cooling operation of the cooling device of the present invention, and the heating control is sequentially performed by reversely controlling the motor 16 by the temperature control circuit of the temperature control device based on the result. It is possible to maintain a constant temperature.
[0039]
Since the heat-dissipating heat exchanger 46 is provided with a protective temperature detector 60 for detecting the temperature of the water-cooled part, the temperature state of the water-cooled part of the Stirling refrigerator is monitored and an abnormality occurs in the refrigerator. When the temperature rises, the operation of the motor for driving the refrigerator is stopped for protection.
[0040]
In addition, since an abnormality occurs in the refrigerator and a sudden pressure rise in the water cooling section cannot be handled by indirect detection of the pressure change by the temperature detector 60, the water pressure installed in the cooling water circulation line 54 is detected. The water pressure detector 50 directly detects an abrupt pressure increase in the water cooling section due to a malfunction of the refrigerator such as a water pump failure, and the operation of the motor for driving the refrigerator is stopped for protection. Thus, even if the hot water hose is not welded as in the refrigerant circuit of the air conditioner, inconveniences such as hose disconnection due to an increase in water pressure can be prevented.
[0041]
In addition, when the detected value of the water pressure detector is equal to or higher than the predetermined value, the operation of the Stirling refrigerator is stopped. When the detected value is lower than the predetermined value, the operation of the Stirling refrigerator is restarted. Alternatively, the operation of the refrigerator may be automatically continued, and when these operations are repeated a plurality of times, the operation of the Stirling refrigerator may be stopped and the operation may be shifted to work for removing the failure.
[0042]
In the above embodiment, the two-piston type Stirling refrigerator 3 is used. However, another type of Stirling refrigerator 3 such as a displacer type may be used, or a pressure switch may be used instead of the water pressure detector 50. Needless to say, it may be used.
[0043]
【The invention's effect】
As described above, the present invention can directly detect the pressure increase even if a chiller abnormality such as a water pump failure occurs and a sudden pressure increase occurs in the water cooling section, and the hose used for the cooling water circulation path is disconnected. It is possible to provide a Stirling refrigerator that can prevent such inconveniences.
[0044]
In addition, the temperature detector monitors the temperature of the water-cooled part of the refrigerator, and if the abnormality occurs in the refrigerator and the temperature rises, the operation of the refrigerator is stopped and protected. Even if a machine abnormality occurs and a sudden pressure increase occurs in the water-cooled section, this pressure increase can be detected directly, and inconveniences such as hose disconnection can be reliably and quickly prevented.
[0045]
In addition, the Stirling refrigerator operation was stopped when the detected value of the water pressure detector was above the predetermined value, and the Stirling refrigerator operation was restarted when the detected value was below the predetermined value. If there is, the operation of the refrigerator is automatically continued, and if these operations are repeated several times, the operation of the Stirling refrigerator can be stopped and the operation for removing the failure can be efficiently performed. .
[Brief description of the drawings]
FIG. 1 is an overall conceptual diagram of a Stirling cooling apparatus.
FIG. 2 is a view showing a Stirling refrigerator of the present invention.
FIG. 3 is a diagram showing temperature control and protection control of the Stirling refrigerator of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Stirling cooling device 2 Case 3 Stirling refrigerator 4 Cooling head 5 Chilled refrigerant line 6 Inlet plug 7 Outlet plug 8 Chilled equipment 9 Outlet end 10 Inlet end 32 Compression shilling 33 Expansion shilling 36 Compression piston 37 High greenhouse (compression space)
41 Low greenhouse (expansion space)
42 expansion piston 50 water pressure detector 55 radiator 60 temperature detector

Claims (3)

A Stirling refrigerator that encloses a working gas and has a cooling head and a heat exchanger for heat dissipation, a cold refrigerant pipe through which a cold refrigerant cooled in the cooling head flows, and one end of the cold refrigerant pipe A cooling refrigerant inlet plug and an outlet plug provided at the other end, and the chilling refrigerant outlet plug and the inlet plug are detachably connected to a refrigeration refrigerant pipe of a refrigeration / utilization device so that the Stirling refrigeration In a Stirling cooling device comprising a cooling refrigerant circulation line formed between a cooling machine and the cold energy utilization device, and conveying cold energy to the cold energy utilization device, a temperature detector is provided in the Stirling refrigerator, and A water pressure detector is provided in a cooling water circulation line formed by connecting a heat dissipation heat exchanger and a heat dissipation device in an annular shape, and the temperature detector and the output of the water pressure detector Stirling cooling apparatus characterized by controlling the rolling. 2. The Stirling cooling apparatus according to claim 1, wherein the Stirling refrigerator is stopped when the detected value of the temperature detector or the water pressure detector exceeds a predetermined value. 2. The Stirling cooling apparatus according to claim 1, wherein the Stirling refrigerator is stopped when the detected value of the water pressure detector is equal to or higher than a predetermined value, and is restarted when the detected value is lower than the predetermined value.

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