JP3353671B2 - Ice storage 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 ice storage type refrigeration apparatus, and more particularly to the reliability of detecting the water level of a heat storage tank and reducing the cost of the apparatus.

[0002]

2. Description of the Related Art In recent years, an ice regenerative refrigeration system has been developed which generates and stores ice at night using inexpensive late-night electric power and uses the ice for cooling in the daytime for the purpose of shifting peak demand for electric power. ing.

As this type of ice storage type refrigerating apparatus, for example, an air conditioner disclosed in Japanese Patent Application Laid-Open No. 7-301438 is known. As shown in FIG. 10, this air conditioner includes a compressor (c), an outdoor heat exchanger (d), an electronic expansion valve (e1), an electronic expansion valve (e2), and an indoor heat exchanger (f).
And a main storage circuit (b) provided with a so-called static type ice storage device (g).

[0004] During the heat storage operation for making ice, the refrigerant circulates as indicated by solid arrows in the figure. That is, the compressor
The refrigerant discharged from (c) is condensed in the outdoor heat exchanger (d), decompressed by the electronic expansion valve (e1), evaporated in the heat transfer coil (h) of the ice heat storage device (g), and Perform a cycle back to (c). At this time, the water stored in the heat storage tank (i) of the ice heat storage device (g) is cooled by the refrigerant and iced.

[0005] On the other hand, during the heat storage utilizing operation using the ice generated as described above, the refrigerant circulates as shown by the dashed arrow in the figure. That is, the refrigerant discharged from the compressor (c) is cooled and condensed in the outdoor heat exchanger (d) to become a liquid refrigerant having a predetermined degree of supercooling. This liquid refrigerant is stored in the heat storage coil (h) of the ice heat storage device (g) in the heat storage tank.
(i) is further cooled by the ice stored therein. The liquid refrigerant flowing out of the heat transfer coil (h) is decompressed by the electronic expansion valve (e2) and expanded to become a gas-liquid two-phase refrigerant. The two-phase refrigerant cools the indoor air by evaporating in the indoor heat exchanger (f) and returns to the compressor (c). Therefore, the electric input of the compressor (c) is reduced by the amount of the cold stored in the ice stored in the heat storage tank (i), and the peak shift of the electric power is achieved.

In this type of air conditioner, the amount of heat storage is controlled based on a water level detected by a water level sensor provided in the heat storage tank (i). In other words, the volume of water expands when it becomes iced, so that when the amount of ice stored in the heat storage tank (i) increases, the water level rises. Therefore, there is a certain correlation between the water level and the heat storage amount, and the heat storage amount can be accurately estimated by detecting the water level.

[0007]

However, conventionally, since a water level sensor was used for detecting the water level, there were the following problems in reliability and economy.

That is, when the water level sensor is used, the sensor main body and its attached equipment are installed in a high humidity environment of 100% humidity in the heat storage tank, so that their electric characteristics are easily deteriorated. Therefore, the reliability of the water level detection has been reduced. In addition, since the water level sensor is an expensive measuring instrument, it has hindered the cost reduction of the entire apparatus. That is, the economics of the apparatus have been reduced.

The present invention has been made in view of the above points, and an object of the present invention is to improve the reliability of water level detection and reduce the cost of the apparatus.

[0010]

In order to achieve the above object, the present invention uses two float switches (71) and (72) as means for detecting the water level of the heat storage tank (16). .

More specifically, the present invention includes a heat storage tank (16) for storing water or ice, and in a heat storage operation, water in the heat storage tank (16) is iced to store cold heat, while a heat storage utilization operation is performed. Sometimes, in an ice storage type refrigerating apparatus that recovers cold heat by melting ice in the heat storage tank (16), the heat storage tank (16) includes a first float switch (71) provided at a predetermined upper limit position, A second float switch (72) provided at a predetermined lower limit position.

When the water level rises to the predetermined upper limit position according to the above-mentioned invention specific matter, the first float switch (7
1) turns ON. On the other hand, when the water level has decreased to the predetermined lower limit position, the second float switch (72) is turned off.
State. Therefore, it is possible to recognize that the water level is within the predetermined range by using both the float switches (71) and (72). Since the float switch is cheaper than the water level sensor, the cost of the device is reduced.

The present invention further provides a heat storage tank at the start of the heat storage operation.
(16) Remaining ice determination means for determining whether or not ice remains
(80, 82) and when the residual ice determination means (80, 82) determines that no ice remains, the heat storage operation is performed for a predetermined time while the residual ice determination means (80, 82) A heat storage control means (80) for executing a heat storage operation until the water level rises to the upper limit position and the first float switch (71) is turned on when it is determined that ice remains.

According to the above-mentioned invention specifying matter, the residual ice determining means (8
0,82) determines that no ice remains in the heat storage tank (16), the heat storage operation is performed for a predetermined time. This allows
A predetermined amount of heat storage is generated without excess or shortage. On the other hand, when the residual ice determining means (80, 82) determines that ice remains, the heat storage operation is continued until the water level of the heat storage tank (16) reaches the position where the first float switch (71) is provided. Done. As a result, excessive ice making is avoided, and damage to the heat storage tank (16) due to excessive volume expansion of water is prevented.

[0015] The invention according to claim 1, further heat storage control means (80), thermal storage operation and the second float switch water level of the heat storage tank (16) is lowered to a lower limit position (72) is turned OFF Is to be prevented.

When the water level in the heat storage tank (16) drops too much due to water leakage or the like, the second float switch (72) switches to the OFF state, and the heat storage operation is not performed. As a result, the heat storage operation in a state where the water level is abnormally lowered is prevented, and damage to the heat storage tank (16) due to excessive ice making is avoided.

According to a second aspect of the present invention, an on-off valve (99) is provided at a predetermined reference water level of the heat storage tank (16), and the on-off valve (99) is opened to open the reference water level. When a reference water level pipe (93) for draining the above water out of the heat storage tank (16) is provided, while the residual ice determining means (80, 82) determines that no ice remains, Prior to the heat storage operation, the on-off valve (99)
And a water level adjusting means (80) for adjusting the water level of the heat storage tank (16) to the reference water level.

When the remaining ice determining means determines that no ice remains according to the above-mentioned invention specific matter, the on-off valve (99) is opened, and the water level of the heat storage tank (16) is adjusted to the reference water level. Therefore, even if dew condensation occurs and the condensed water mixes into the water in the heat storage tank (16), the water amount in the heat storage tank (16) is adjusted to an appropriate amount at the start of the heat storage operation, so that the water is always maintained at a constant reference state. The heat storage operation is started. Therefore, reliable and stable heat storage operation is performed.

The invention described in claim 3 is the invention according to claim 1 or 2
In the ice storage type refrigerating apparatus according to (1), a compressor (11, 12) for compressing the refrigerant, a heat source side heat exchanger (14) for condensing or evaporating the refrigerant, and a decompression mechanism (23, 18) for decompressing the refrigerant And a use-side heat exchanger (19) for evaporating or condensing the refrigerant, and a heat transfer coil (17) provided to be immersed in the water of the heat storage tank (16) and exchanging heat between the refrigerant and water or ice. And a refrigerant circuit (3) provided with the compressor (11, 1) during the heat storage operation.
2) condensing the refrigerant from the heat source side heat exchanger (14),
The pressure is reduced by the pressure reducing mechanism (23), evaporated by the heat transfer coil (17), and during the heat storage utilization operation, the refrigerant from the compressor (11, 12) is condensed by the heat transfer coil (17) to reduce the pressure. The pressure is reduced by the mechanism (18) and evaporated by the use side heat exchanger (19).

According to the above aspect of the invention, during the heat storage operation, the water in the heat storage tank (16) is cooled and iced by evaporating the refrigerant in the heat transfer coil (17). as a result,
Cold heat is stored in the heat storage tank (16). On the other hand, during the heat storage operation, the ice in the heat storage tank (16) is melted by the refrigerant condensing in the heat transfer coil (17). As a result, the heat storage tank (1
6) The cold heat is recovered. Therefore, a so-called static type ice heat storage is performed.

[0021]

Embodiments of the present invention will be described below with reference to the drawings.

-Configuration of the air conditioner (1)-As shown in Fig. 1, the air conditioner (1) includes an outdoor unit.
(101) an ice heat storage unit (102) provided with a heat storage tank (16)
, And indoor units (103), (103), ..., which are connected through a refrigerant pipe to form a refrigerant circuit (3).
Is formed. First, the overall configuration of the air conditioner (1) centering on the refrigerant circuit (3) will be described, and then the heat storage tank (1) will be described.
The configuration of 6) will be described.

(Overall Configuration) As shown in FIG. 1, the refrigerant circuit (3) includes a main circuit (30), an indoor side circuit (50), and a heat storage utilization circuit (60).

The main circuit (30) is a circuit through which a refrigerant circulates when ice is generated in the heat storage tank (16). The main circuit (30) is provided in parallel with a first compressor (11) and a second compressor (12). ), Four-way switching valve (13), outdoor heat exchanger (14) as a heat source side heat exchanger, first electronic expansion valve (1
5), liquid receiver (21), first solenoid valve (SV1), second pressure reducing mechanism
Electronic expansion valve (23), heat transfer coil (17) immersed in water stored in heat storage tank (16), two-way solenoid valve (26), four-way switching valve described above
(13) and an accumulator (22) are connected in order.

The indoor side circuit (50) is a circuit for supplying a refrigerant to the outdoor unit (101) for the purpose of cooling or heating the room, and one end (51) is provided with a first solenoid valve in the main circuit (30). (SV1) and the second electronic expansion valve (23).
(52) is connected between the two-way solenoid valve (26) and the four-way switching valve (13). In the indoor side circuit (50), in order from one end (51),
Indoor electronic expansion valves (18), (18), ... and indoor heat exchangers (19), (1
9), ... are provided.

The heat storage utilization circuit (60) is a circuit through which refrigerant flows when recovering cold from ice, and the upstream end (61) is a main circuit.
(30) is connected between the liquid receiver (21) and the first solenoid valve (SV1), and the downstream end (62) is connected to the heat transfer coil (17) and the bidirectional solenoid valve (2).
6) is connected between. In the heat storage utilization circuit (60), the second solenoid valve (SV2) and the first check valve (C
V1) is provided.

Compressors (11) and (12) of main circuit (30), four-way switching valve (13), outdoor heat exchanger (14), first electronic expansion valve (15), liquid receiver (21) , And the accumulator (22) are housed in an outdoor unit (101) installed outdoors. Further, the outdoor unit (101) is provided with outdoor fans (24), (24) for supplying air to the outdoor heat exchanger (14).

The first solenoid valve (SV1), the second electronic expansion valve (23), the heat transfer coil (17), the heat storage tank (16), and the heat storage utilization circuit (60) of the main circuit (30) It is stored in the unit (102). Further, the ice heat storage unit (102) is provided with a controller (80) for executing heat storage control and the like described later. The controller (80) functions as a heat storage control unit, a residual ice determination unit, and a water level adjustment unit in the present invention.

The indoor electronic expansion valve (18) and the indoor heat exchanger (19) of the indoor side circuit (50) are housed in each indoor unit (103). Further, the indoor units (103), (103),... Have indoor fans (2) for supplying air to the indoor heat exchangers (19), (19),.
5) and (25) are provided.

Between the compressors (11) and (12) and the four-way switching valve (13), a high-pressure pressure sensor for detecting the pressure of the gas discharged from the compressors (11) and (12), ie, high pressure. (27) is provided.
On the other hand, between the compressors (11) and (12) and the accumulator (22), a low-pressure pressure sensor (28) for detecting the pressure of the intake gas of the compressors (11) and (12), that is, the low pressure, is provided. Have been.

The main components of the air conditioner (1) have been described above. The present air conditioner (1) further includes the following auxiliary components.

In the outdoor unit (101), an oil separator (201) is provided on the discharge side of the first compressor (11).
An oil return pipe (20) having a capillary tube (CP1) is provided between the oil separator (201) and the suction side of the first compressor (11).
2) is provided. The first compressor (11) and the second compressor (1
A pressure equalizing tube (203) provided with a capillary tube (CP2) is provided between the pressure equalizing tube (2) and the pressure equalizing tube (2). First in the main circuit (30)
From between the electronic expansion valve (15) and the liquid receiver (21), a solenoid valve (SV
4), (SV4) and auxiliary circuits (204), (204) each having a capillary tube (CP3), (CP3) are connected to each of the compressors (11), (12). A gas pipe (205) having a check valve (CV2) is provided between the liquid receiver (21) and the discharge pipe of the compressors (11) and (12). This gas pipe (205) has a solenoid valve (SV
5) is provided, and the pipe (206) connected to the upstream pipe of the accumulator (22) is connected.

In the ice heat storage unit (102), an auxiliary circuit (207) having a capillary tube (CP4) and a check valve (CV3) has one end having a second electronic expansion valve (23) and a heat transfer coil (1).
7), and the other end is connected between the two-way solenoid valve (26) and the connection end (52) of the indoor circuit (50). Also,
The upstream end is the connection end (51) of the indoor side circuit (50) and the second electronic expansion valve.
(23), and an auxiliary circuit (208) whose downstream end is connected between the upstream end (61) of the heat storage utilization circuit (60) and the second solenoid valve (SV2). . This auxiliary circuit (208) includes:
A check valve (CV4) that allows only the refrigerant flow in the direction from the upstream end to the downstream end is provided.

The refrigerant circuit (3) includes a plurality of filters.
(F), (F),... Are provided as appropriate.

The discharge side pipes of the first compressor (11) and the second compressor (12) are provided with high pressure switches (29) and (29), respectively.

(Configuration of heat storage tank (16)) FIGS. 2 to 4 show heat storage tanks in a state before connecting pipes.
The configuration of (16) is shown. The heat storage tank (16) has side plates (122), (123), (1
This is a rectangular parallelepiped tank composed of 24), (125), an upper plate (121) and a bottom plate (126).

As shown in FIG. 2, a reference water level port (97) is provided above the front side plate (122). The reference water level port (97) is a through hole provided at a position that becomes the reference water level at the start of the heat storage operation. A reference water level pipe (93) provided with a water drain valve (99) comprising an electromagnetic valve as an on-off valve is connected to the reference water level port (97). Therefore, at the time of water level adjustment, by opening the drain valve (99), the water located above the reference water level is allowed to flow through the reference water level port (97) and the reference water level pipe (9).
The wastewater is treated outside the tank through 3), and the water level is adjusted to the standard water level. At a predetermined position (upper limit position) diagonally above the reference water level port (97), a first mounting port (111) as a through hole for mounting the first float switch (71) is provided.
At a predetermined position (lower limit position) diagonally below (97), a second mounting port (112) as a through hole for mounting the second float switch (72) is provided. A water temperature sensor (8) for detecting the temperature of water in the heat storage tank (16) is located below the front of the heat storage tank (16).
A third mounting port (113) for mounting 2) is provided.

As shown in FIG. 3, an overflow water outlet (96) is provided above one side surface (123) adjacent to the side plate (122).
And a water supply port (95). The overflow water discharge port (96) is used to discharge water that exceeds a predetermined maximum water level outside the tank so that the amount of water and ice (water content) stored in the heat storage tank (16) does not exceed a predetermined amount. This is a through hole for discharging. An overflow pipe (92) is connected to the overflow water discharge port (96). Therefore, when the water level of the heat storage tank (16) rises to the position of the overflow water discharge port (96), the water is naturally discharged through the overflow pipe (92). The overflow water outlet (96) is located at the water level position when the rated amount of heat is stored, that is, the heat storage tank (16) that stores the water at the reference water level.
Is provided at a water level position after storing ice heat of a predetermined rating. A water supply pipe (91) connected to a water supply source (not shown) is connected to the water supply port (95), and water is supplied to the heat storage tank (16) through the water supply pipe (91). The overflow water discharge port (96) and the water supply port (95) are formed at a predetermined interval from each other so that the overflow pipe (92) and the water supply pipe (91) do not come into contact with each other.

As shown in FIG. 11, the first float switch (71) and the second float switch (72) are installed such that the float unit (75) and the electrical unit (76) are arranged in the horizontal direction. A type of float switch, that is, a so-called horizontal mounting type float switch. The first float switch (71) is mounted so as to penetrate the first mounting port (111), the float part (75) is located inside the heat storage tank (16), and the electric equipment part (76) is connected to the heat storage tank. It is installed so as to be located outside (16). Similarly, the second float switch (72)
Is mounted in a state penetrating the second mounting port (112), and the float part (75) is located inside the heat storage tank (16),
The electrical component (76) is installed so as to be located outside the heat storage tank (16). As a result, the electrical components (76) of each of the float switches (71), (72) are provided so as not to be exposed to the high humidity atmosphere in the heat storage tank (16).

The first float switch (71), the second float switch (72) and the drain valve (99) are connected to a controller (80) via a signal line. When the second float switch (72) is turned off, the controller (80)
(16) It is configured to determine that water is insufficient and to issue a predetermined alarm.

Although not shown, the bottom plate (1) of the heat storage tank (16) is not shown.
26) is provided with a discharge port, and a drain pipe (94) having an on-off valve is connected to the discharge port.

Here, a water supply port (95), an overflow water discharge port (96), a reference water level port (97), a first float switch (7)
1) and the positional relationship of the second float switch (72) in the vertical direction will be described. That is, each height will be described.

As shown in FIG. 5, the reference water level port (97) is provided at a position of a predetermined reference water level N. The overflow water discharge port (96) is provided above the reference water level N by a water level rise A caused by a rated amount of heat storage. First
The float switch (71) has a predetermined height B higher than the reference water level N.
Only above. Here, the predetermined height B is based on the amount of heat due to the latent heat change (ice formation) of water and 0 ° C.
When it is assumed that the sum of the amount of heat due to the sensible heat change when the temperature changes to the predetermined temperature (25 ° C.) becomes the above-mentioned rated heat storage amount,
The water level displacement corresponding to the latent heat change. The second float switch (72) is provided below the position where the first float switch (71) is provided by a water level rise C by the maximum possible heat storage amount of the heat storage tank (16). That is, the second float switch (72) is provided at a position where the water level cannot rise to the height of the first float switch (71) even if heat storage is started from a lower water level. .

-Operation of the air conditioner (1)-Next, the operation of the air conditioner (1) will be described. By switching the state of the four-way switching valve (13), the present air conditioner (1) can selectively execute a cooling operation or a heating operation in addition to the heat storage operation for storing cold heat. Here, the heat storage operation will be described first, and then the cooling operation using the heat storage (heat storage use operation) will be described.

(Heat storage operation) In the heat storage operation, for example, inexpensive electricity at night is used to store heat in a heat storage tank.
(16) is an operation for generating ice as a heat storage material. First,
The operation of circulating the refrigerant in the refrigerant circuit (3) will be described, and then the heat storage control, which is one of the features of the present invention, will be described.

In this operation, the four-way switching valve (13) is set on the solid line side shown in FIG. The first electronic expansion valve (15) is set to a fully open state, while the second electronic expansion valve (23) is controlled to a predetermined opening according to the operating state. The first solenoid valve (SV1) and the bidirectional solenoid valve (26) are set in the open state, and the second solenoid valve (SV1) is opened.
V2) is set to the closed state.

The refrigerant circulates as shown by solid arrows in FIG. In FIG. 6, the circulation path of the refrigerant is emphasized by a bold line.

That is, the high-temperature and high-pressure gas refrigerant discharged from the compressors (11) and (12) passes through the four-way switching valve (13) and then flows into the outdoor heat exchanger (14). The gas refrigerant condenses by performing heat exchange with outdoor air in the outdoor heat exchanger (14),
After passing through the liquid receiver (21), it flows into the ice heat storage unit (102) from the outdoor unit (101), is decompressed by the second electronic expansion valve (23), and expands into a two-phase refrigerant. The two-phase refrigerant evaporates in the heat transfer coil (17). At this time, the refrigerant is stored in the heat storage tank (16)
The water is cooled and the water is frozen. In other words, the heat transfer coil
Generate ice around (17). Then, the low-pressure refrigerant that has flowed out of the heat transfer coil (17) returns to the outdoor unit (101) again, passes through the four-way switching valve (13) and the accumulator (22), and then passes through the compressors (11) and (12). ).

The heat storage control is executed according to the flowchart shown in FIG. That is, when the heat storage operation is started in step ST1, in step ST2, the heat storage tank is started.
(16) It is determined whether or not the water temperature Tw0 is lower than the predetermined temperature T0. The predetermined temperature T0 is a reference temperature for judging whether or not ice remains in the heat storage tank (16) at the start of the heat storage operation, and is set to 7 ° C. in the present embodiment. As a result, if the water temperature Tw0 is equal to or higher than the predetermined temperature T0, the process proceeds to step ST3, where the water temperature Tw0 is set to the predetermined temperature T0
If smaller, the process proceeds to step ST6.

Steps ST3 to ST5 are performed in the heat storage tank (1).
6) shows the operation to be performed when no ice remains, that is, the process of the residual ice operation. In step ST3, the operation mode is set to the residual ice operation by setting the operation determination flag to 0FF. Next, proceeding to step ST4, the water drain valve (99) is opened to adjust the water level of the heat storage tank (16) to the reference water level. Thereafter, the drain valve (99) is closed, and the refrigerant is circulated in the refrigerant circuit (3) for a predetermined time t1 to perform an ice making operation. That is, in the non-residual ice operation, the heat storage amount is managed based on the operation time regardless of the ON / OFF state of the first float switch (71). Then, when it is determined in step ST5 that the predetermined time t1 has elapsed, the process proceeds to step ST8, and the heat storage operation ends.
As a result, a predetermined amount of ice heat storage is accurately and accurately generated in the heat storage tank (16).

On the other hand, steps ST6 to ST7 show an operation to be executed when ice remains in the heat storage tank (16), that is, a step of residual ice operation. In step ST6,
The operation determination flag is set to ON, and the operation mode is set to the residual ice operation. Then, the refrigerant circulation operation is started.
Next, proceeding to step ST7, the first float switch (71)
Is determined to be in the ON state. That is, it is determined whether or not the water level has risen to a position where the first float switch (71) is provided. As a result, when the first float switch (71) is in the OFF state, the operation is continued, while when the first float switch (71) is in the ON state, the process proceeds to step ST8 to end the heat storage operation. That is, in the residual ice operation, the heat storage amount is managed based on the water level. The reason why the heat storage amount is managed based on the water level instead of the operation time is as follows.

That is, in the residual ice operation, since ice remains in the heat storage tank (16) at the start of the operation, if the heat storage operation is performed for a predetermined time in the same manner as in the non-residual ice operation, excessive heat will be stored in the heat storage tank (16). May produce ice. In this case, the heat transfer coil (17) and the heat storage tank (16) may be subjected to excessive stress due to the volume expansion of the water, which may cause breakage or the like. Therefore, in order to prevent excessive freezing in the heat storage tank (16) and to reliably avoid damage to the heat transfer coil (17) and the heat storage tank (16), in the residual ice operation, the heat storage amount is determined based on the water level. Managing.

(Heat-storage operation) The heat-storage operation is an operation for cooling the room by using ice in the heat storage tank (16) as a cold heat source at the time of peak power demand, for example, during the daytime. First, the refrigerant circulation operation will be described.

The four-way switching valve (13) is set on the solid line side shown in FIG. First electronic expansion valve (15) and second electronic expansion valve (23)
Are set to the fully open state, and the indoor electronic expansion valves (18), (18),... Are controlled to a predetermined opening degree according to the operation state. 1st solenoid valve (S
V1) and the two-way solenoid valve (26) are set to a closed state, and the second solenoid valve (SV2) is set to an open state.

The refrigerant circulates as shown by solid arrows in FIG. In FIG. 8 as well, the circulation path of the refrigerant is indicated by a thick line.

That is, the high-temperature and high-pressure gas refrigerant discharged from the compressors (11) and (12) flows into the outdoor heat exchanger (14) via the four-way switching valve (13), and the outdoor heat exchanger ( In 14), heat exchange is performed with outdoor air to condense. After the refrigerant flowing out of the outdoor heat exchanger (14) passes through the liquid receiver (21), the ice heat storage unit
(102) into the heat transfer coil (17). This refrigerant is cooled by the ice stored in the heat storage tank (16) in the heat transfer coil (17), and recovers the stored cold heat. The refrigerant flowing out of the heat transfer coil (17) passes through the second electronic expansion valve (23) and flows into each of the indoor units (103), (103),. In each indoor unit (103), the refrigerant is decompressed by the indoor electronic expansion valve (18), becomes a low-temperature two-phase refrigerant, and flows into the indoor heat exchanger (19). The refrigerant flowing into the indoor heat exchanger (19) exchanges heat with the indoor air, evaporates, and cools the indoor air. The refrigerant flowing out of the indoor heat exchanger (19) passes through the four-way switching valve (13) and the accumulator (22) of the outdoor unit (101) and is sucked into the compressors (11) and (12).

Such a refrigerant circulating operation is performed for a predetermined time according to the cooling load. However, when the temperature of the water in the heat storage tank (16) reaches a predetermined upper limit temperature Tmax, it is regarded that the heat storage has been consumed, and the heat storage is used. The operation is switched from the operation that has been performed to the cooling operation that does not use heat storage.

By the way, even if all the ice is in a molten state, the water temperature in the tank is close to 0 ° C., and is sufficiently low.
Therefore, not only ice but also water in the heat storage tank (16) can be used as a cold heat source. Therefore, the cold heat stored in the heat storage tank (16) can be roughly classified into cold heat caused by a change in latent heat of water and cold heat caused by a change in sensible heat. Therefore, whether or not all the heat storage has been consumed is determined based on whether or not the water temperature of the heat storage tank (16) has reached a predetermined upper limit water temperature Tmax.

In the present air conditioner (1), the upper limit water temperature Tmax is changed according to the operation mode of the heat storage operation. As shown in FIG. 9, after starting the heat storage utilizing operation in step ST11, in step ST12, a determination of the heat storage operation mode is performed.

When the determination flag is set to OFF, it is determined that the heat storage operation mode is the residual ice operation,
Proceeding to step ST14, the upper limit water temperature Tmax is set to the first predetermined temperature T.
1, that is, set to 20 ° C.

On the other hand, if the determination flag is set to ON, it is determined that the heat storage operation mode is the residual ice operation, and the routine proceeds to step ST13, where the upper limit water temperature Tmax is set to the second predetermined temperature T2. Since the residual ice operation generates less heat storage than the residual ice operation, more sensible heat is used after the residual ice operation than after the residual ice operation. Therefore, the second predetermined temperature T2 is equal to the first predetermined temperature T
It is set to a temperature higher than 1 and here 25 ° C
Stipulated.

After setting the upper limit water temperature Tmax in step ST14 or step ST13, the process proceeds to step ST15, in which the above-described refrigerant circulation operation is performed, and the room is cooled.

—Effects of Air Conditioner (1) — As described above, the air conditioner (1) uses the float switches (71) and (72) instead of using the water level sensor. Since the float switch is unlikely to fail even under high humidity conditions, the water level can be reliably detected, and the reliability of heat storage control can be improved. In particular, in this air conditioner (1), the horizontally mounted float switch (7
1) and (72) are used. In the horizontally mounted float switch, the electrical component (76) to which the signal line is connected is located outside the heat storage tank (16), so that the electrical component (76) can be isolated from a high humidity environment. Therefore, float switches (71), (7
2) is less likely to fail. As a result, the reliability of the entire apparatus can be improved, and the reliability of control of heat storage can be further improved.

Further, since the float switch is less expensive than the water level sensor, it is possible to configure the apparatus at a lower cost. That is, the cost of the apparatus can be reduced.

Generally, the surface of the heat transfer coil (17) and the heat storage tank (1
Since the inner wall surface of 6) is at a low temperature lower than the dew point of air, dew condensation may occur, and condensed water may enter the water in the heat storage tank (16). Therefore, the water content of the heat storage tank (16) may increase. However, in this embodiment, when no ice remains at the start of the heat storage operation, the drain valve (99) of the reference water level pipe (93) is opened so that the water level of the heat storage tank (16) becomes the reference water level. The water level is adjusted. Therefore, the initial state at the start of the heat storage operation can always be kept constant. Therefore, since the relationship between the heat storage amount and the water level in the heat storage operation can be kept constant, the amount of generated heat can be accurately grasped.

When there is no residual ice at the start of the heat storage operation, the heat storage operation is performed for a predetermined time.
Even if the condensed water mixes with the water in the heat storage tank (16) during the heat storage operation, an appropriate amount of heat storage can be generated without excess or shortage without being affected. In addition, overflow pipe (92)
Is provided, the increased water due to condensation is naturally discharged out of the tank through the overflow pipe (92). Therefore, it is possible to prevent water from overflowing from the heat storage tank (16).

On the other hand, when ice remains in the heat storage tank (16) at the start of the heat storage operation, the amount of heat storage is controlled not based on the operation time but on the water level. Therefore, it is possible to reliably prevent the heat transfer coil (17) and the heat storage tank (16) from being damaged due to an excessive amount of generated ice.

When the amount of water in the heat storage tank (16) is excessively insufficient due to water leakage or the like, the water level is set to the first float switch during the residual ice operation even if all the water in the tank is frozen. It may not be possible to rise to the position (71). If the amount of moisture is excessively short, the heat storage operation will be performed for a long time, and the heat transfer coil
(17) and the heat storage tank (16) may be damaged. But,
According to the present air conditioner (1), since the second float switch (72) for protecting the device is provided, when the amount of water is insufficient, the second float switch (72) is turned off, and Is transmitted, and the heat storage operation is stopped. That is, the heat storage operation is not performed. Therefore, the reliability of the device is further improved.

A water temperature sensor (82) is provided in the heat storage tank (16), and the presence or absence of residual ice is determined based on the water temperature of the heat storage tank (16) detected by the water temperature sensor (82). The determination of the presence or absence of residual ice at the start can be performed easily and accurately.

Regarding the heat storage operation, the amount of sensible heat to be used is changed according to the operation mode of the previous heat storage operation. In other words, if the heat storage operation is residual ice operation,
During the heat storage operation, the sensible heat is used until the water in the heat storage tank (16) reaches 25 ° C. Therefore, the available amount of heat storage can be increased, and shortage of heat storage can be avoided.

The refrigeration system in the present invention is a refrigeration system in a broad sense, and is not limited to the above-described air conditioner, but also includes a refrigeration system and a refrigerator in a narrow sense.

[0072]

As described above, according to the present invention , the water level is detected by two float switches instead of the water level sensor, so that the reliability of the water level detection can be improved. Further, cost reduction of the device can be achieved.

When there is no residual ice at the start of the heat storage operation, the heat storage operation is performed for a predetermined time, so that a constant amount of heat storage can always be generated without excess or shortage. On the other hand, if there is residual ice at the start of the heat storage operation, the heat storage operation is terminated when the water level reaches a predetermined position, so that excessive ice making can be avoided and the heat storage tank is reliably prevented from being damaged. Can be.

According to the first aspect of the present invention, it is possible to reliably avoid the heat storage operation in a state where the water level is abnormally lowered, and to prevent the heat storage tank from being damaged due to excessive ice making.

According to the second aspect of the present invention, when there is no residual ice at the start of the heat storage operation, the heat storage operation is performed after adjusting the water level of the heat storage tank to the reference water level. You can start from the reference state. for that reason,
A reliable and stable heat storage operation can be performed.

According to the third aspect of the invention, the effects of the first or second aspect of the invention can be obtained in a so-called static type device.

[Brief description of the drawings]

FIG. 1 is a refrigerant circuit diagram of an air conditioner.

FIG. 2 is a front view of a heat storage tank.

FIG. 3 is a side view of the heat storage tank.

FIG. 4 is a top view of the heat storage tank.

FIG. 5 is a diagram showing the relationship between the position of each port and the mounting position of each float switch.

FIG. 6 is a refrigerant circuit diagram illustrating the circulation of the refrigerant during the heat storage operation.

FIG. 7 is a flowchart of heat storage control.

FIG. 8 is a refrigerant circuit diagram showing refrigerant circulation during a heat storage utilization operation.

FIG. 9 is a flowchart of a heat storage operation.

FIG. 10 is a refrigerant circuit diagram of a conventional air conditioner.

FIG. 11 is a side view of a horizontally mounted float switch.

[Explanation of symbols]

 (1) Air conditioner (3) Refrigerant circuit (11), (12) Compressor (14) Outdoor heat exchanger (19) Indoor heat exchanger (16) Heat storage tank (17) Heat transfer coil (71) First Float switch (72) Second float switch (75) Float section (76) Electrical section (80) Controller (82) Water temperature sensor (91) Water supply pipe (92) Overflow pipe (93) Standard water level pipe (99) Water drain valve

Continuation of the front page (56) References JP-A-9-33090 (JP, A) JP-A-7-293949 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) F28D 20 / 02 F24F 5/00 102 F25B 13/00 351 F25C 1/00 F25C 1/00 301

Claims (3)

(57) [Claims] 1. A heat storage tank (16) for storing water or ice.
During the heat storage operation, the water in the heat storage tank (16) is frozen to cool
During operation using heat storage, ice in the heat storage tank (16)
In an ice storage refrigeration unit that recovers cold heat by melting
Te, the heat storage tank (16) is first off provided at a predetermined upper limit position
A funnel switch (71) and a third switch provided at a predetermined lower limit position.
Equipped with a two-float switch (72) to check whether ice remains in the heat storage tank (16) at the start of heat storage operation
The remaining ice determining means (80 , 82) and the remaining ice determining means (80, 82) determine that no ice remains.
When the heat storage operation is performed for a predetermined time,
If the determination means (80, 82) determines that the ice remains,
The water level rises to the upper limit position and the first float switch (71)
Storage control means for executing the thermal storage operation until the power supply is turned on
(80), the heat storage control means (80), the water level of the heat storage tank (16) is the lower limit position
And the second float switch (72) turns off.
That it is configured to prevent heat storage operation
Characteristic ice storage refrigeration system. 2. A heat storage tank (16) for storing water or ice.
During the heat storage operation, the water in the heat storage tank (16) is frozen to cool
During operation using heat storage, ice in the heat storage tank (16)
In an ice storage refrigeration unit that recovers cold heat by melting
Te, the heat storage tank (16) is first off provided at a predetermined upper limit position
A funnel switch (71) and a third switch provided at a predetermined lower limit position.
Equipped with a two-float switch (72) to check whether ice remains in the heat storage tank (16) at the start of heat storage operation
The remaining ice determining means (80 , 82) and the remaining ice determining means (80, 82) determine that no ice remains.
When the heat storage operation is performed for a predetermined time,
If the determination means (80, 82) determines that the ice remains,
The water level rises to the upper limit position and the first float switch (71)
Storage control means for executing the thermal storage operation until the power supply is turned on
(80), and an on-off valve (9) is located at a predetermined reference water level in the heat storage tank (16).
9), and the reference water is opened by opening the on-off valve (99).
A standard water level pipe for draining water above the heat storage tank (16)
While (93) is provided, the remaining ice determination means (80, 82) has determined that no ice remains.
In some cases, the on-off valve (99) is opened prior to the heat storage operation,
The water level adjusting means (8) for adjusting the water level of the heat storage tank (16) to the reference water level
0) An ice storage type refrigerating apparatus characterized by comprising: 3. An ice storage type refrigerating apparatus according to claim 1 or 2.
The compressor (11, 12) compresses the refrigerant, and condenses or evaporates the refrigerant.
The heat source side heat exchanger (14) to generate heat and a decompressor to decompress the refrigerant
Structure (23,18) and user side heat exchange to evaporate or condense refrigerant
Heat exchanger (19) and the heat storage tank (16).
Heat transfer coil (17) for exchanging heat between refrigerant and water or ice
And a refrigerant circuit (3) provided with a refrigerant circuit.When the heat storage operation is performed, the refrigerant from the compressor (11, 12)
Condensed in the heat source side heat exchanger (14) and reduced by the pressure reducing mechanism (23)
During the heat storage operation, the refrigerant from the compressors (11, 12) is compressed and evaporated by the heat transfer coil (17).
Condensed in the heat transfer coil (17), depressurized by the decompression mechanism (18),
Ice characterized by being evaporated in the use side heat exchanger (19)
Thermal storage refrigeration equipment.