JP3455441B2 - Absorption refrigerator - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an absorption refrigerating machine, and more particularly to an absorption refrigerating machine having a device for removing uncondensed hydrogen gas generated inside the machine.

[0002]

2. Description of the Related Art Absorption refrigerators operating in an absorption refrigeration cycle have been known as cooling devices.
Attention is paid to advantages such as good energy efficiency during operation, and there is an increasing demand for an absorption chiller capable of performing not only cooling operation but also heat pump heating operation using heat drawn from outside air by an evaporator. For example, Japanese Examination 6
Japanese Patent Publication No. 97127 proposes an absorption chiller-heater that can be operated in three modes: cooling operation, heating by heat pump operation, and heating by direct-fired (boiler) operation.

Since the absorption refrigeration cycle of the absorption refrigerating machine is performed under a high vacuum, a very small amount is caused by the catalytic reaction between the components in the refrigerant and the metal material forming the refrigerant flow path and the corrosion inhibitor. Non-condensable gas such as hydrogen gas is generated. It is known that this non-condensed gas lowers the vacuum degree of the absorber, the evaporator, etc., which are components that should maintain a high vacuum degree, and significantly reduces the operating efficiency of cooling and heating. For this reason, it is necessary to perform maintenance for discharging the non-condensable gas to the outside of the machine using an extraction means such as a vacuum pump at regular intervals.

JP-A-8-121911 and JP-A-5-121911
No. 9001 discloses a device for discharging non-condensable gas generated in an absorption refrigerator to the outside of the device. In these devices, a non-condensable gas separated from a refrigerant liquid is guided to a hydrogen release tube made of a heated palladium tube, and the non-condensable gas is released to the atmosphere by utilizing the selective permeability of palladium. .

[0005]

The absorption refrigerator having the above non-condensable gas discharge device has the following problems. In an absorption refrigeration apparatus that uses an alcohol-based refrigerant such as a fluorinated alcohol for the absorption refrigeration cycle, by mixing water in the refrigerant, it is possible to suppress corrosion of the metal material forming the refrigerant flow path. Are known. In this case, since the mixed water reacts with the aluminum forming the refrigerant flow path to generate a slight amount of hydrogen gas, it is necessary to remove it. The generation of hydrogen gas is due to the following anode reaction and cathode reaction. Anode reaction: Al → Al ³
+ 3e ⁻ , Al ³ + 3OH → AlOOH · H ₂ O (hydration of aluminum ion (boehmite film formation)), cathode reaction: 3H + 3e ⁻ → 3 / 2H ₂ (hydrogen generation).

However, in the non-condensable gas discharge device disclosed in the above publication, the generated hydrogen gas is discharged to the outside of the machine, so that the structure for maintaining the airtightness inside the machine becomes complicated. It will be. Further, since the water content contained in the refrigerant is gradually reduced, there is a problem in that an appropriate amount of water necessary for suppressing corrosion cannot be secured. Further, there is a structural restriction that the hydrogen releasing pipe or the storing means (sleeve-shaped member or the like) of the hydrogen releasing pipe has to be largely projected from the gas extracting member to the outside.

In view of the above-mentioned problems, the present invention can remove the generated non-condensed gas without lowering the degree of vacuum in the machine and while maintaining the water content in the refrigerant at an appropriate amount. An object is to provide an absorption refrigerator.

[0008]

DISCLOSURE OF THE INVENTION The present invention for solving the above-mentioned problems and for achieving the object is an absorption refrigerator using an alcohol-based refrigerant and having a cylindrical shape with one end closed and the other end open. The body is provided with a heater holder configured such that a rod-shaped heater can be detachably attached from the other end and a hydrogen removing agent can be held on an outer surface thereof, and the heater holder has the hydrogen removing agent in a space communicating with a passage of the refrigerant. It is characterized in that it is arranged so as to expose.

According to this feature, the generated hydrogen gas diffuses and flows into the space and comes into contact with the hydrogen removing agent, and the hydrogen gas is removed. Further, a heater is attached to the heater holder holding the hydrogen removing agent, and heating of the heater accelerates the hydrogen removing action of the hydrogen removing agent.

[0010]

DETAILED DESCRIPTION OF THE INVENTION The present invention will be described in detail below with reference to the drawings. FIG. 7 is a system block diagram showing a main configuration of an absorption refrigerator according to an embodiment of the present invention. Note that, here, an absorption type cooling / heating device is assumed as one embodiment of the absorption type refrigerator. The evaporator 1 contains a fluoroalcohol such as trifluoroethanol (TFE) as a refrigerant, and the absorber 2 contains a DMI derivative (dimethylimidazolidinone) as a solution containing an absorbent. The refrigerant is not limited to fluoroalcohol, and may be any one that can have a wide non-freezing range. The solution is not limited to the DMI derivative and can be a wide amorphous range, and may be TFE, that is, an absorbent having a normal pressure boiling point higher than that of the refrigerant and capable of absorbing the refrigerant.

The evaporator 1 and the absorber 2 are fluidly connected to each other via an evaporation (refrigerant) passage, and when the evaporator 1 and the absorber 2 are kept under a low pressure environment of, for example, about 30 mmHg. The refrigerant in the evaporator 1 evaporates, and this refrigerant vapor enters the absorber 2 via the evaporation passage. In the absorber 2, the absorbent solution absorbs the refrigerant vapor to perform the absorption refrigeration operation. A precooler 18 is provided in the evaporation passage for heating the mist (fog-like refrigerant) remaining in the refrigerant vapor to vaporize it, and for lowering the temperature of the TFE fed from the condenser 9. Has been.

When the burner 7 is ignited, the regenerator 3 increases the solution concentration in the absorber 2 (the burner, regenerator and solution concentration will be described later). Absorber 2
When the high-concentration solution therein absorbs the refrigerant vapor, the refrigerant inside the evaporator 1 evaporates, and the inside of the evaporator 1 is cooled by the latent heat during the evaporation. The evaporator 1 is provided with a pipeline 1a through which cold water passes. It is preferable to use an aqueous solution of ethylene glycol or propylene glycol as the cold water flowing through the conduit 1a. One end (outlet end in the figure) of the pipeline 1a is the # 1 opening of the first four-way valve V1, and the other end (inlet end in the figure) is the second.
Are connected to the # 1 openings of the four-way valve V2.

The refrigerant is guided by the pump P1 to the spraying means 1b provided in the evaporator 1 and sprayed onto the pipe line 1a through which cold water passes. The refrigerant takes heat of evaporation from the cold water in the pipeline 1a to become refrigerant vapor, and the temperature of the cold water in the pipeline 1a, which has been deprived of heat by the refrigerant, drops. The refrigerant vapor flows into the absorber 2 through the evaporation passage. The refrigerant in the evaporator 1 is guided to the spraying means 1b, and part of it is filtered by the filter 4
It is also fed to the rectification device 6 through. A flow rate control valve V5 is provided between the evaporator 1 and the filter 4.

When the vapor of the fluorinated alcohol, that is, the refrigerant vapor is absorbed by the solution in the absorber 2, the temperature of the solution rises due to the absorption heat. The absorption capacity of the solution is higher as the temperature of the solution is lower and the solution concentration is higher. Therefore, in order to suppress the temperature rise of the solution, a pipe line 2a through which cooling water passes is provided inside the absorber 2. After one end (outlet end in the figure) of the pipe 2a passes through the inside of the condenser 9, the pump P
3 is connected to the # 2 opening of the first four-way valve V1, and the other end (inlet in the figure) of the conduit 2a is connected to the # 2 opening of the second four-way valve V2. The same aqueous solution as the cold water is used as the cooling water passing through the pipe 2a.

The solution is guided by the pump P2 to the spraying means 2b provided in the absorber 2 and sprayed on the conduit 2a. As a result, the solution is cooled by the cooling water passing through the conduit 2a. On the other hand, since the cooling water absorbs heat, its temperature rises. When the solution in the absorber 2 absorbs the refrigerant vapor and the concentration of the absorbent decreases, the absorption capacity decreases. Therefore,
The regenerator 3 and the rectifier 6 separate and generate the refrigerant vapor from the absorbent solution to increase the concentration of the solution and recover the absorption capacity.

The solution diluted with the absorption of the refrigerant vapor in the absorber 2, that is, the dilute liquid, is guided to the spraying means 2b, and is also fed by the pump P2 to the rectifier 6 through the pipe 7b to the regenerator 3. Run down. An opening / closing valve V3 is provided in a pipe line 7b connecting the pump P2 and the regenerator 3. The regenerator 3 is provided with a burner 7 that heats the dilute liquid supplied from the absorber 2. The burner 7 is preferably a gas burner, but may be any other type of heating means.

The solution (concentrated liquid), which is heated in the regenerator 3 and whose refrigerant vapor is extracted to increase the concentration, is returned to the absorber 2 through the pipe line 7a. An on-off valve V4 is provided on the conduit 7a. The concentrated liquid is sprayed on the conduit 2a by the spraying means 2c.

When the rare liquid fed to the regenerator 3 is heated by the burner 7, refrigerant vapor is generated. The absorbent solution mixed in the refrigerant vapor is separated in the rectification unit 6, and the refrigerant vapor having a higher purity is fed to the condenser 9. The refrigerant vapor is cooled in the condenser 9 to be condensed and liquefied, and the precooler 1
8. Returned to the evaporator 1 via the pressure reducing valve 11. This refrigerant is sprinkled on the pipeline 1a.

Although the purity of the vapor supplied from the condenser 9 to the evaporator 1 is extremely high, the absorbent component, which is only slightly mixed in the reflux refrigerant, accumulates during a long operation cycle, and the evaporator is evaporated. It is inevitable that the purity of the refrigerant in 1 gradually decreases. Decrease in the purity of the refrigerant by feeding a small part of the refrigerant from the evaporator 1 to the rectifier 6 through the filter 4 and carrying out a cycle for increasing the purity again with the refrigerant vapor generated from the regenerator 3. Is suppressed.

The high-temperature concentrated liquid in the pipe 7a coming out of the regenerator 3 came out of the absorber 2 by the heat exchanger 12 provided in the middle of the pipe connecting the absorber 2 and the rectifier 6. After being cooled by exchanging heat with the dilute liquid, it is sprayed in the absorber 2. on the other hand,
The diluted liquid preliminarily heated by the heat exchanger 12 is fed to the rectifier 6. Although the thermal efficiency is improved in this way, a heat exchanger (not shown) for transferring the heat of the concentrated liquid to be refluxed to the cooling water in the pipe 2a discharged from the absorber 2 or the condenser 9. By providing (1), the temperature of the concentrated liquid recirculated to the absorber 2 can be further lowered and the cooling water temperature can be further raised.

The sensible heat exchanger 14 for exchanging the cold water or the cooling water with the outside air is provided with a pipe line 4a, and the indoor unit 15 is provided with a pipe line 3a. One end (inlet end in the figure) of each of the pipelines 3a, 4a is at the # 3 and # 4 openings of the first four-way valve V1, and the other end (outlet end in the figure) is # at the second four-way valve V2.
3 and # 4 openings, respectively. The indoor unit 15 is provided in a room for cooling and heating, and is provided with a fan for blowing cold air or hot air (both are common) 10 and an outlet (not shown). The sensible heat exchanger 14 is placed outdoors, and the fan 19 forcibly exchanges heat with the outside air.

The evaporator 1 is provided with a level sensor L1 for detecting the amount of refrigerant, a temperature sensor T1 for detecting the temperature of the refrigerant, and a pressure sensor PS1 for detecting the pressure inside the evaporator 1. The absorber 2 is provided with a level sensor L2 that senses the amount of the solution. The condenser 9 is provided with a level sensor L9 that senses the amount of condensed refrigerant, a temperature sensor T9 that senses the temperature of the refrigerant, and a pressure sensor PS9 that senses the pressure inside the condenser 9. Sensible heat exchanger 1
4, the regenerator 3, and the indoor unit 15 are provided with temperature sensors T14, T3, and T15, respectively. The temperature sensor T14 of the sensible heat exchanger 14 senses the outside air temperature, and the temperature sensor T15 of the indoor unit 15 senses the temperature of the room to be cooled and heated. The temperature sensor T3 of the regenerator 3 senses the temperature of the solution.

In the above construction, during the cooling operation, the first four-way valve V1 and the second four-way valve V2 communicate with their respective # 1 and # 3 openings while # 2 and # 2.
Switch so that the four openings communicate. By this switching, the cold water whose temperature has been lowered by spraying the refrigerant is supplied to the indoor unit 1
The interior of the room is cooled by being guided to the conduit 3a of No. 5.

On the other hand, during the heating operation, the first four-way valve V1 and the second four-way valve V1 are switched so that the # 1 and # 4 openings are communicated with each other and the # 2 and # 3 openings are communicated with each other. By this switching, the warmed cooling water is guided to the conduit 3a of the indoor unit 15 to heat the room.

When the outside air temperature becomes extremely low during the heating operation, it becomes difficult to draw heat from the outside air through the sensible heat exchanger 14, and the heating capacity is lowered. For such a case, a recirculation passage 9a and an on-off valve 17 that bypass between the condenser 9 and the regenerator 3 (or the rectifier 6) are provided. That is, when it is difficult to pump up the heat from the outside air, the absorption refrigeration cycle operation is stopped, the steam generated in the regenerator 3 is circulated to the condenser 9, and the heat of heating by the burner 7 is transferred to the inside of the condenser 9. In order to improve the heating capacity, the temperature of the cooling water is raised by the direct-fired operation that is efficiently conducted to the cooling water in the pipeline 2a.

Next, the hydrogen gas removing device provided in the cooling and heating device will be described. 3 is a perspective view of a condenser to which a hydrogen gas removing device is attached, and FIG. 4 is a sectional view of the same. In both figures, the condenser 9 comprises a main body 91 and a hydrogen removal tank 92. The hydrogen removal tank 92 and the condenser body 91 are integrally connected by welding or the like via a partition wall 93. The partition wall 93 is provided with an opening 94 so that a fluid can flow between the hydrogen removal tank 92 and the condenser body 91. In the condenser 9, generated hydrogen gas H
₂ is accumulated so as to adhere to the liquid surface 95 by the flow of TFE vapor. The hydrogen gas H ₂ diffuses in the condenser 9 during the suspension of operation. The opening 94 is
It is set at a position slightly higher than the liquid level 95 of the refrigerant in the condenser 9 so that the accumulated hydrogen gas H ₂ can flow into the hydrogen removal tank 92 by a concentration gradient, that is, diffusion.

The hydrogen removal tank 92 is provided with a hydrogen removal assembly 96 for removing the inflowing hydrogen gas H ₂ . The hydrogen removing assembly 96 is inserted into the holder 97 provided so as to project inside the hydrogen removing tank 92, the heater holder 98 formed in the holder 97 and fixed by screwing the screw, and the hole 98 a of the heater holder 98. It is composed of a heater (not shown) to be used. The heater holder 98 is provided with a reducing unit for removing hydrogen gas by reacting with hydrogen gas H ₂ to generate water. Details of the heater holder 98 and the returning unit will be described later with reference to FIG.

On the wall surface of the condenser body 91, the connecting portion 99 of the circulation passage 9a for supplying the refrigerant to the regenerator 3 (or the rectifier 6) and the connecting portion 10 of the pipe passage 2a through which the cooling water passes.
0, a connecting portion 101 with the rectifier 6 and the like are attached.

Next, the heater holder 98 will be described in detail with reference to the sectional view of FIG. In the figure, the heater holder 98 includes a bottomed cylindrical base portion 98b made of a stainless material (for example, SUS304) and a reducing portion 98c provided around the base portion 98b. The base portion 98b includes a male screw 98d that fits the female screw of the holder 97, and a head 98e having a shape that fits with a tool such as a spanner or a wrench when screwed.

The reducing portion 98c can be formed of, for example, a sinter-molded metal oxide (hydrogen removing agent) so as to cover the base portion 98b. As the metal oxide, a transition metal oxide alone or a mixture of transition metal oxides can be used. For example, a simple substance of NiO or a mixture containing NiO as a main component and further CuO, MnO ₂ , and Al ₂ O ₃ is preferably used. The reducing portion 98c is not limited to a molded metal oxide, and may be a sintered metal oxide small piece or powder. When holding these small pieces or powders on the base 98c, it is advisable to wrap them together with the base 98c with a filter made of a net or a cylindrical body having a large number of through holes.

FIG. 2 is a cross-sectional view of essential parts showing a state in which small pieces or powders of metal oxide are held on the base portion 98c by a filter.
In the figure, the filter 103 is a tubular body in which a large number of holes 104 (see enlarged view EL) are formed, and a large number of metal oxide powder or small pieces 105 are held between the tubular body 103 and the base portion 98b and reduced. It constitutes the part 98c. Hydrogen gas H ₂ can flow through the holes 104 and come into contact with the metal oxide powder or small pieces 105.

FIG. 5 is an external view of a heater used by being inserted into the heater holder 98. Rod-shaped heater 102
Is made up of a resistor (not shown) wrapped in an insulator (outer skin), and a current is supplied to the resistor through a lead wire 106. The rod-shaped heater 102 is used by inserting it into the heater holder 98, but it is not always inserted.
It can be removed and inserted as required. For example, 1 per week
It can be inserted into the heater holder 98 for hydrogen gas removal at the time of maintenance about once, and can be removed at other times. As the heater 102, a well-known heater may be used which causes a current to flow through a resistor to generate heat.

During operation, the hydrogen gas H ₂ flowing into the hydrogen removal tank 92 through the opening 94 is heated by the heater holder 98.
Reacts with the reducing portion 98c formed on the outer surface of the metal, that is, the metal oxide, the metal oxide is reduced to produce water, and hydrogen gas is removed. That is, a chemical reaction according to the following formula (f1) occurs. _{MOx + xH 2 = M + xH} 2 O ... (f1). Here, the symbol M is a transition metal, and x is a constant. The generated water flows into the condenser 9 through the opening 94.

In this way, water is produced when the hydrogen gas accumulated in the condenser 9 is removed, so that the water content in the refrigerant flowing through the refrigerant passage will not decrease with the hydrogen gas removing action. Absent. Therefore, the amount of water mixed in the refrigerant in order to suppress the corrosion of the metal material forming the refrigerant passage is maintained.

The above metal oxide may be only those listed above, or an appropriate amount of an additive such as a compound having a catalytic action for promoting the reaction between the metal oxide and hydrogen gas may be mixed.

Although the condenser body 91 and the hydrogen removal tank 92 are formed in close contact with each other or integrally formed so that hydrogen gas or water can pass through the opening 94, the arrangement is not limited to this arrangement, and the condenser body 91 is not limited thereto. Alternatively, the hydrogen removal tanks 91 may be arranged in close proximity to each other, and the two may be connected by a pipe. In this case, the condenser body 9 of the pipe
It goes without saying that the end on the first side is installed so as to open at a position slightly higher than the liquid surface 95.

FIG. 6 is a sectional view showing a modified example of the heater holder 98. In the figure, a flange 107 is provided on the open end side of the heater holder 98, and the end of the flange 107 is folded back to the sealing portion of the heater holder 98, that is, the bottom side to form a cap shape. An internal thread 108 is formed on the inner surface of the flange 107 having the cap-shaped folded portion.
Is formed. On the other hand, the holder 97 is formed with a male screw for fitting with the female screw 108 of the heater holder 98.

As described above, the heater holder 98 formed with the internal thread or the external thread is screwed to the holder 97 fixed to the hydrogen removal tank 92 to remove hydrogen while keeping the hydrogen removal tank 92 airtight. be able to. In addition, since the airtightness is further increased in the screwed portion between the heater holder 98 and the holder 97, it is needless to say that a seal tape or the like for pipe coupling can be used together.

The reaction with aluminum, which is one of the structural members of the air conditioner, occurs mainly in the condenser 9 which is a high temperature / high pressure part. From this point of view, the hydrogen removal tank 9
2 is provided integrally with the condenser 9, but not limited to this configuration,
The coolant may be arranged at another place as long as it communicates with the place where the coolant passes.

The hydrogen removal tank 92 is not limited to the box type shown in FIG. 3, but may be, for example, a cylindrical type arranged concentrically with the heater holder 98. In short, the heater holder 92 holding the metal oxide can be housed,
It suffices to provide a space in which the heater holder 92 and hydrogen gas can be kept in contact with each other.

In the present embodiment, the heater holder 98
A screw was formed on this and the screw on the side of the hydrogen removal tank 92 was adapted to be fixed in an airtight holding state. However, without forming a screw in the heater holder 98, a hole through which a set screw can pass is provided in the head portion 98e, while a screw hole to which the set screw is fitted is formed in the holder 97, and the heater holder 98 and the holder 97 are formed by the set screw. And may be combined. In short, it is sufficient that the heater holder 98 is easily replaced, and that the seal is provided so as not to impair the airtightness of the refrigerant passage.

[0042]

As is apparent from the above description, according to the inventions of claims 1 to 4, hydrogen gas is removed by the hydrogen removing agent. In particular, according to the invention of claim 2, the heater holder holding the hydrogen removing agent is screwed to the machine body, so that it can be easily attached and detached and high airtightness can be maintained. Further, according to the invention of claim 3, water is generated by the reducing action of the oxide and hydrogen gas is removed. Further, according to the invention of claim 4, hydrogen gas can be efficiently removed at a position where hydrogen gas is easily generated.

As described above, according to the inventions of claims 1 to 4, high operating efficiency can be maintained without lowering the degree of vacuum of the refrigerant passage, and the generated water is not discharged outside the machine. In particular, the water content of the refrigerant mixed with water can be appropriately maintained. Further, the heater can be attached to the heater holder only when necessary, and since the heater holder is arranged so that the hydrogen removing agent is exposed in the space communicating with the refrigerant passage, the protruding portion to the outside can be reduced.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of a heater holder of a hydrogen removing device.

FIG. 2 is a cross-sectional view showing a modified example of a heater holder.

FIG. 3 is a perspective view of a condenser having a hydrogen removing device.

FIG. 4 is a sectional view of a condenser having a hydrogen removing device.

FIG. 5 is an external view of a rod-shaped heater.

FIG. 6 is a sectional view showing a further modification of the heater holder.

FIG. 7 is a system diagram showing a configuration of an absorption type cooling and heating apparatus according to an embodiment of the present invention.

[Explanation of symbols]

1 ... Evaporator, 2 ... Absorber, 3 ... Regenerator, 9 ... Condenser, 14 ... Sensible heat exchanger, 15 ... Indoor unit, 19 ... Fan, 91 ... Condenser body, 92 ... Hydrogen removal tank,
93 ... Partition wall, 94 ... Opening, 95 ... Refrigerant liquid level, 9
7 ... Holder, 98 ... Heater holder, 98b ... Base part,
98c ... reducing part, 98d ... male screw, 98e ... head,
102 ... Heater, 103 ... Filter, 104 ...
Hole, 105 ... Metal oxide, 106 ... Lead wire, 10
7 ... Flange, 108 ... Female thread

─────────────────────────────────────────────────── --- Continuation of the front page (56) Reference JP-A-9-104862 (JP, A) JP-A-5-187744 (JP, A) JP-A-63-254362 (JP, A) JP-A-60- 205161 (JP, A) JP-A-57-153171 (JP, A) JP-A-1-244261 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) F25B 43/04 F25B 15 / 00

Claims (4)

(57) [Claims] 1. An absorption refrigerator using an alcohol-based refrigerant, which is a cylindrical body having one end closed and the other end open, a rod-shaped heater being detachable from the other end, and hydrogen being removed on the outer surface. An absorption refrigerating machine comprising: a heater holder configured to be capable of holding an agent, wherein the heater holder is arranged so as to expose the hydrogen removing agent in a space communicating with a passage of the refrigerant. 2. A heater is formed on the heater holder side, while a screw adapted to the screw is formed on the machine body side forming a space communicating with the refrigerant passage, and the heater holder is formed by screwing these screws together. The absorption refrigerating machine according to claim 1, wherein the absorber is fixed to a body member. 3. The absorption refrigerating machine according to claim 1, wherein the hydrogen removing agent is a transition metal oxide simple substance or a mixture of transition metal oxides. 4. The absorption type according to claim 1, wherein the space communicating with the refrigerant passage is a tank having a communication opening with the refrigerant liquid level of the condenser. refrigerator.