JP4794909B2 - Drinking water dispenser - Google Patents

Description

  The present invention relates to a drinking water dispenser.

The structure of a conventional ice bank type drinking water dispenser is described in, for example, Patent Document 1 and the like. Of such drinking water dispensers, the structure of a dispenser for providing cold water is shown in FIG. The drinking water dispenser 140 includes a cooling water tank 141, and a tubular evaporator (cooler) 142 is wound around the inner peripheral surface of the cooling water tank 141 in order to cool the cooling water in the cooling water tank 141. A compressor, a condenser, and an expansion valve (or capillary tube) (not shown) are sequentially connected to the evaporator 142 to constitute a refrigeration apparatus. When a refrigerant such as gas circulates in the refrigeration apparatus, the evaporator 142 performs heat exchange between the refrigerant and the cooling water to cool the cooling water, and ice is formed in the cooling water tank 141.
Ice grows in a plate shape around the evaporator 142 so that the thickness gradually increases. At this time, the stirring motor 146 stirs the cooling water so that the ice thickness grows uniformly.
On the other hand, the cooling coil 143 is connected to the water supply. When the pouring cock is operated to pour out cold water, drinking water is supplied from the water supply to the cooling coil 143. When the drinking water flows through the cooling coil 143, the drinking water is cooled by exchanging heat with the cooling water. The cooled drinking water is poured out as cold water from the pouring cock.

JP 2003-165600 A

The operation of such a drinking water dispenser 140 is shown in FIG.
The drinking water dispenser 140 is turned on at time T800. With the operation of the refrigeration system, the temperature of the cooling water decreases and reaches 0 ° C. at time T802. Since the cooling water is stirred and uniformly cooled by the stirring motor 146, the cooling water is not frozen immediately after the time T802, and the water temperature continues to decrease and the cooling water enters a supercooled state. This is the supercooling water temperature zone shown in FIG. At this time, the drinking water in the cooling coil 143 cooled by the cooling water is also in a supercooled state.
Thereafter, at time T804, for example, icing on the evaporator 142 occurs, the cooling water temperature rises as the ice grows, and the supercooled state is eliminated.

However, in the conventional drinking water dispenser as described above, there is a problem that cotton ice is generated in the cooling coil 143 due to the impact at the time of pouring in the time zone when the drinking water in the cooling coil 143 is supercooled. It was.
For this reason, for example, cotton ice may be compressed and crystallized by the water pressure at the time of pouring, grow as a lump of ice, clog the cooling coil 143, and may not be able to provide drinking water normally. In addition, for example, when drinking water freezes, the volume increases by about 10%, which increases the pressure in the cooling coil 143, breaks the cooling coil 143 or its surrounding beverage path, and causes water leakage. May end up.

  This invention was made in order to solve such a problem, and it aims at providing the drinking water dispenser which prevents generation | occurrence | production of the cotton ice in a cooling coil.

In order to solve the above-described problem, a drinking water dispenser according to the present invention includes a cooling water tank that stores cooling water that cools drinking water, and a refrigeration apparatus that includes an evaporator that cools the cooling water. The electronic linear expansion valve varies the circulation amount of the refrigerant according to the opening degree of the electronic linear expansion valve, and the electronic linear expansion valve controls the opening degree of the electronic linear expansion valve. by, more uniformly cool the entire evaporator, and the whole cooled state, to cool the more locally predetermined portion of the expansion valve side of the evaporator, Ri can der switched to a local cooling conditions, the temperature of the cooling water A cooling water temperature detecting means for detecting, and when the cooling water temperature detected by the cooling water temperature detecting means is equal to or lower than a predetermined set water temperature set below the melting point of the cooling water; A expansion valve is switched to the local cooling condition, then, when a predetermined time has elapsed, the electronic linear expansion valve Ru is switched to the entire cooling state.
Further, a drinking water dispenser according to the present invention includes a cooling water tank for storing cooling water for cooling drinking water, and a refrigeration apparatus including an evaporator for cooling the cooling water, and the refrigeration apparatus is an electronic linear expansion for expanding the refrigerant. The electronic linear expansion valve varies the circulation amount of the refrigerant according to the opening degree of the electronic linear expansion valve, and the electronic linear expansion valve makes the electronic linear expansion valve more uniform by controlling the opening degree of the electronic linear expansion valve. Cooling water temperature detecting means for detecting the cooling water temperature, which can be switched between a whole cooling state for cooling the whole evaporator and a local cooling state for cooling a predetermined portion on the expansion valve side of the evaporator more locally. And an icing detection means for detecting whether or not the cooling water is frozen in the vicinity of a predetermined portion on the expansion valve side of the evaporator, and the cooling detected by the cooling water temperature detection means When the water temperature of the electronic linear expansion valve is lower than the predetermined set water temperature set below the melting point of the cooling water, the electronic linear expansion valve is switched to the local cooling state. The electronic linear expansion valve is switched to the entire cooling state.
Further, a drinking water dispenser according to the present invention includes a cooling water tank for storing cooling water for cooling drinking water, and a refrigeration apparatus including an evaporator for cooling the cooling water, and the refrigeration apparatus is an electronic linear expansion for expanding the refrigerant. The electronic linear expansion valve varies the circulation amount of the refrigerant according to the opening degree of the electronic linear expansion valve, and the electronic linear expansion valve makes the electronic linear expansion valve more uniform by controlling the opening degree of the electronic linear expansion valve. Cooling water temperature detecting means for detecting the cooling water temperature, which can be switched between a whole cooling state for cooling the whole evaporator and a local cooling state for cooling a predetermined portion on the expansion valve side of the evaporator more locally. And an icing detection means for detecting whether or not the cooling water is frozen in the vicinity of a predetermined portion on the expansion valve side of the evaporator, and the cooling detected by the cooling water temperature detection means When the water temperature of the electronic linear expansion valve is switched to the local cooling state when the icing detection means detects that the cooling water is not frozen, and the predetermined temperature elapses Thus, the electronic linear expansion valve is switched to the entire cooling state.
Further, a drinking water dispenser according to the present invention includes a cooling water tank for storing cooling water for cooling drinking water, and a refrigeration apparatus including an evaporator for cooling the cooling water, and the refrigeration apparatus is an electronic linear expansion for expanding the refrigerant. The electronic linear expansion valve varies the circulation amount of the refrigerant according to the opening degree of the electronic linear expansion valve, and the electronic linear expansion valve makes the electronic linear expansion valve more uniform by controlling the opening degree of the electronic linear expansion valve. Cooling water temperature detecting means for detecting the cooling water temperature, which can be switched between a whole cooling state for cooling the whole evaporator and a local cooling state for cooling a predetermined portion on the expansion valve side of the evaporator more locally. And an icing detection means for detecting whether or not the cooling water is frozen in the vicinity of a predetermined portion on the expansion valve side of the evaporator, and the cooling detected by the cooling water temperature detection means When the water temperature is below a predetermined set water temperature and the icing detection means detects that the cooling water is not frozen, the electronic linear expansion valve is switched to the local cooling state, and then the icing detection means is cooled. When the water icing is detected, the electronic linear expansion valve is switched to the entire cooling state.

  According to the present invention, the drinking water dispenser locally cools a predetermined portion of the evaporator, so that the cooling water freezes at an early stage to eliminate the supercooled state and prevents the generation of cotton ice in the cooling coil. To do.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
Embodiment 1 FIG.
In FIG. 1, the structure of the drinking water dispenser 1 which concerns on this invention is shown. The drinking water dispenser 1 includes a water supply pipe 2, and a beverage supply port 4 is provided at one end of the water supply pipe 2. The beverage supply port 4 is connected to a beverage supply means (not shown) such as a water supply.
The drinking water dispenser 1 includes a cooling water tank 6 that stores cooling water for cooling drinking water. A portion of the cooling water tank 6 excluding the top plate is covered with a heat insulating material to insulate the inside and the outside. In the cooling water tank 6, a cooling coil 8 that cools while storing or transporting drinking water is provided and connected to the water supply pipe 2. The cooling coil 8 is formed by forming a material having high thermal conductivity and corrosion resistance into a coiled tube, and for example, a stainless pipe is used.
One end of the extraction pipe 32 is connected to the downstream end of the cooling coil 8. The other end of the extraction pipe 32 is provided with an extraction cock 34 for extracting cold water using water pressure.

An evaporator 10 for cooling the cooling water in the cooling water tank 6 is provided in the cooling water tank 6. The evaporator 10 has a coil shape surrounding the cooling coil 8. The water level of the cooling water is, for example, the cooling water level 6a, and is at a position where at least the coiled portion of the evaporator 10 is submerged in the cooling water.
The evaporator 10, the compressor 12, the condenser 14, the dryer 13, and the electronic linear expansion valve 16 are sequentially connected to constitute a refrigeration apparatus, and the refrigerant circulates in the direction of the arrow a in the refrigeration apparatus. A fan motor 36 for cooling the condenser 14 is also provided. This refrigeration apparatus compresses the refrigerant gas in the compressor 12, forcibly cools and condenses it in the condenser 14 with the fan motor 36, removes moisture and the like in the dryer 13, and expands it in the electronic linear expansion valve 16, It is evaporated in the evaporator 10 and returned to the compressor 12.
The electronic linear expansion valve 16 includes a pulse motor, and is electrically controlled to change the circulation amount of the refrigerant.

The refrigerant expanded through the electronic linear expansion valve 16 is vaporized inside the evaporator 10, whereby the cooling water in the cooling water tank 6 is cooled and freezes around the periphery 11 of the evaporator 10. This ice is used as a heat storage material to ensure the ability to continuously pour out a large amount of cold water.
In addition, in this Embodiment, although the condenser 14 is forced air cooling by the fan motor 36, this may be a water-cooled condenser.

In this refrigeration apparatus, pressure sensors for detecting the pressure of the refrigerant are provided at both ends of the compressor 12. That is, the low pressure side pressure sensor 28 provided on the suction side of the compressor 12 and the high pressure side pressure sensor 29 provided on the discharge side of the compressor 12.
On the discharge side (low pressure side) of the electronic linear expansion valve 16, a refrigerant inlet temperature sensor 20 is attached at a position where the evaporator 10 is not submerged in the cooling water (that is, a position above the cooling water level 6a), and the refrigerant at the evaporator inlet 10a is Detect temperature. Further, the refrigerant inlet temperature sensor 20 is covered with a heat insulating material 40 so as not to be affected by the outside temperature. The front end of the heat insulating material 40 is a position where the heat insulating material 40 is not submerged in the cooling water, and the front end of the heat insulating material 40 is bound so that the cooling water does not enter the inside from the front end of the heat insulating material 40.
In the evaporator outlet 10b, a refrigerant outlet temperature sensor 22 is attached at a position where the evaporator 10 is not submerged in the cooling water, and detects the temperature of the refrigerant at the evaporator outlet 10b. The refrigerant outlet temperature sensor 22 is covered with a heat insulating material 42 so as not to be affected by the outside temperature. Similar to the heat insulating material 40, the tip of the heat insulating material 42 is a position where it is not submerged in the cooling water, and the tip is bound.

In addition, in the vicinity of the evaporator inlet 10a and immediately below the water surface 10c, which is the part immediately after the evaporator 10 enters the cooling water, ice accumulating detection means for detecting whether or not ice has adhered to the evaporator 10, A presence sensor 23 is provided.
Further, in the cooling water tank 6, a cooling water temperature sensor 24 that is a cooling water temperature detecting means for detecting the temperature of the cooling water and an ice storage sensor 26 for detecting the amount of ice in the cooling water tank 6 are provided. The ice storage sensor 26 determines whether the amount of ice stored in the vicinity of the evaporator 10 (ice storage amount) is less than the first ice storage amount, the first ice storage amount or more, and the second ice storage amount. Detect if the amount of ice is over. Here, the second ice storage amount is larger than the first ice storage amount, for example, full ice.

In the vicinity of the center of the cooling water tank 6, a stirring motor 30 is provided as stirring means for stirring the cooling water in the cooling water tank 6 in order to efficiently cool the drinking water in the cooling coil 8. The agitating motor 30 has a propeller at its tip, and rotates this to agitate the cooling water to improve the cooling capacity. The cooling water circulates in the direction of arrow b.
The agitation motor 30 is always continuously operated during the operation of the drinking water dispenser 1 to constantly agitate the cooling water in the cooling water tank 6, thereby efficiently cooling the drinking water in the cooling coil 8. Further, the cooling water is forcibly circulated by stirring to make the cooling water temperature uniform, and the ice (heat storage material) frozen and stored in the evaporator 10 is uniformly used to improve the efficiency of heat exchange.

The drinking water dispenser 1 includes a control device (not shown) that controls the electronic linear expansion valve 16. In addition to the electronic linear expansion valve 16, the control device includes a refrigerant inlet temperature sensor 20, a refrigerant outlet temperature sensor 22, a cooling water temperature sensor 24, an ice storage sensor 26, a low pressure side pressure sensor 28, a high pressure side pressure sensor 29, The fan motor 36 and the compressor 12 are electrically connected.
The control device receives the outputs of the refrigerant inlet temperature sensor 20, the refrigerant outlet temperature sensor 22, the ice presence / absence sensor 23, the cooling water temperature sensor 24, and the ice storage sensor 26, and sends a pulse to the electronic linear expansion valve 16 in response thereto. By doing so, the expansion valve control of the electronic linear expansion valve 16 is performed. The electronic linear expansion valve 16 is controlled by a two-stage opening degree. That is, when the opening is relatively large and the entire evaporator 10 is cooled relatively uniformly (hereinafter referred to as “overall cooling state”), the opening is relatively small and only the evaporator inlet 10a is localized and concentrated. The other part, for example, the evaporator outlet 10b is not cooled so much (hereinafter referred to as “local cooling state”). The control device stores in advance the number of pulses generated to control the electronic linear expansion valve 16 to each state.

Further, the control device controls the operation of the refrigeration apparatus according to the output of the ice storage sensor 26. When the ice storage amount is less than the first ice storage amount, the refrigeration apparatus is operated until the second ice storage amount is reached. When the ice storage amount reaches the second ice storage amount, the refrigeration apparatus is stopped until the ice storage amount becomes less than the first ice storage amount.
Furthermore, a control apparatus memorize | stores the value regarding the temperature and time used as the reference | standard which controls a freezing apparatus so that change is possible. The values relating to the temperature are a set water temperature that is a reference for the temperature of the cooling water, an inlet set temperature that is a reference for the temperature of the evaporator inlet 10a, and an outlet set temperature that is a reference for the temperature of the evaporator outlet 10b. Values relating to time are time parameters P <b> 1 to P <b> 6 described in each embodiment described later.

Operation | movement of the drinking water dispenser 1 comprised as mentioned above is demonstrated below.
FIG. 2 is a graph showing time on the horizontal axis and the state of the drinking water dispenser 1 on the vertical axis. Graph (1) shows the operating state of the refrigeration apparatus and the agitation motor 30. Graph (2) shows the amount of ice stored in the evaporator 10 detected by the ice storage sensor 26. Graph (3) shows the temperature of the evaporator inlet 10a, the temperature of the evaporator outlet 10b, and the temperature of the cooling water detected by the refrigerant inlet temperature sensor 20, the refrigerant outlet temperature sensor 22, and the cooling water temperature sensor 24. In the graphs (1) to (3), the horizontal axis is common.

At time T100, the drinking water dispenser 1 that has not been operated is turned on. Since the ice storage amount of the graph (2) detected by the ice storage sensor 26 is less than the first ice storage amount, the refrigeration apparatus is operated. Further, the stirring motor 30 is always continuously operated, and the cooling water in the cooling water tank 6 is cooled while being stirred so as to uniformly contact the evaporator 10. The electronic linear expansion valve 16 is totally cooled.
As shown in the graph (3), the cooling water temperature decreases with the operation of the refrigeration apparatus, and enters a supercooling temperature range below 0 ° C. (melting point of cooling water). The cooling water temperature further decreases and reaches the set water temperature at time T102. The set water temperature may be a value lower than the melting point of the cooling water, but is preferably about −0.5 ° C. or higher. In this example, it is -0.5 degreeC. In the graph (3), a line indicating the set water temperature is shown lower than the actual temperature for easy viewing.

  When the cooling water temperature becomes equal to or lower than the set water temperature, the control device switches the electronic linear expansion valve 16 from the overall cooling state to the local cooling state. As a result, the circulation amount of the refrigerant is reduced and the evaporator inlet 10a is locally cooled. Then, ice begins to form in the vicinity of the portion 10c immediately below the water surface of the evaporator 10, and grows in the supercooled cooling water to give heat to the cooling water, so that the cooling water temperature rises to eliminate the supercooling state, and the cooling water temperature Ice storage operation can be performed with the temperature maintained at 0 ° C. For this reason, the supercooling of drinking water does not occur and the generation of cotton ice is prevented.

  The control device holds the electronic linear expansion valve 16 in the local cooling state for a predetermined cooling time P1 (for example, 10 minutes) from time T102 when the cooling water temperature reaches the set water temperature, and at time T104 when the cooling time P1 has elapsed. Return to total cooling. After time T104, the entire evaporator 10 is cooled substantially uniformly. By changing the length of the cooling time P1, the initial ice mass amount immediately after the drinking water dispenser 1 starts operation can be controlled.

Thereafter, since the ice storage amount reaches the second ice storage amount at time T120, the control device stops the operation of the refrigeration apparatus. Also, for example, at time T122, the dispensing of the beverage is started by the user's operation. This beverage pouring is continued until time T126, for example. As the beverage is poured out, heat is taken from the replenished drinking water and the cooling water temperature rises. In addition, the ice that is the heat storage means melts, and the ice that has been stored is reduced. Since the ice storage amount becomes less than the first ice storage amount at time T124, the control device restarts the operation of the refrigeration apparatus.
At time T124, not all of the ice has melted, and a portion of the ice remains stored, so that no supercooled state occurs even when the refrigeration apparatus resumes operation. If a supercooling state occurs due to a continuous water injection by the user for a long time and all the ice melts, the same control as that after time T102 is performed.
Thereafter, at time T128, the ice storage amount reaches the second ice storage amount, and thus the operation of the refrigeration apparatus is stopped in the same manner as at time T120.

As described above, according to the first embodiment, the drinking water dispenser 1 includes the electronic linear expansion valve 16, and when the cooling water is in a supercooled state, the predetermined portion (evaporator inlet 10a) of the evaporator 10 is provided. Since it cools locally, the cooling water freezes at an early stage, thereby eliminating the supercooled state at an early stage. For this reason, since drinking water does not become a supercooled state, cotton ice does not generate | occur | produce and the freezing in the cooling coil 8 can be prevented. This avoids a serious defect that the beverage cannot be dispensed.
Moreover, breakage of the beverage circuit due to abnormal pressure in the cooling coil 8 and water leakage associated therewith can be avoided.
In general, an ice bank type drinking water dispenser is cooled by cooling water in a water tank, and ice is used to enable concentrated mass extraction as a heat storage material. For this reason, even if there is no ice, if the cooling water is cooled by the refrigeration apparatus, beverage cooling and pouring can be performed. However, in the conventional drinking water dispenser, if there is no ice stored by concentrated mass extraction, a supercooled state will repeatedly occur. As a result, cotton ice is generated, the beverage circuit is clogged, and the beverage cannot be dispensed. That is, cold water cannot be provided continuously. On the other hand, according to the above-described first embodiment, since the supercooled state is eliminated at an early stage, cotton ice is not generated and the beverage circuit is not clogged, so that cold water can be continuously supplied.

In the first embodiment described above, the following modifications can be made.
The control device monitors the temperature of the evaporator outlet 10b detected by the refrigerant outlet temperature sensor 22, and performs protection control to bring the electronic linear expansion valve 16 into the entire cooling state when the temperature exceeds a predetermined limit value. You may go.
By this protection control, abnormal heating of the evaporator outlet 10b can be prevented, and accidents due to overheating and damage to the drinking water dispenser 1 can be prevented.

Further, the control device monitors the suction side pressure of the compressor 12 detected by the low pressure side pressure sensor 28, and when this pressure becomes a predetermined limit value or less, the electronic linear expansion valve 16 is brought into the entire cooling state. Protection control may be performed.
By this protection control, it is possible to prevent the refrigerant in the refrigeration apparatus from being in a vacuum state, and it is possible to prevent a decrease in cooling efficiency and damage to the drinking water dispenser 1 due to vacuum operation.

  Furthermore, in the drinking water dispenser 1, a drive system by inverter control may be used for the compressor 12. In this case, since the circulating flow rate of the refrigerant can be controlled by changing the rotation speed of the compressor 12 without changing the state of the electronic linear expansion valve 16, the refrigeration apparatus is switched between the local cooling state and the whole cooling state. Can do. Since the same effect as described above can be obtained in this way, it is not necessary to use the electronic linear expansion valve 16 as the expansion valve, and the configuration of the expansion valve can be simplified.

Embodiment 2. FIG.
The second embodiment changes the control method of the electronic linear expansion valve 16 in the first embodiment. Hereinafter, differences from the first embodiment will be described.
After the electronic linear expansion valve 16 enters the local cooling state at time T102, the control device monitors the temperature of the evaporator inlet 10a detected by the refrigerant inlet temperature sensor 20, and performs a predetermined inlet temperature holding time P2 (for example, 10 minutes). Only) at a predetermined inlet set temperature.
For example, as shown in FIG. 2, when the temperature of the evaporator inlet 10a becomes lower than the inlet set temperature, for example, −10 ° C. at time T106, the controller linearly changes the electronic linear expansion valve 16 from the local cooling state to the total cooling state ( Switch between stepwise and coordinated). As a result, the state in which the evaporator inlet 10a is locally cooled is eliminated, so that the temperature of the evaporator inlet 10a rises and exceeds the inlet set temperature. When the inlet set temperature is exceeded, the control device linearly switches the electronic linear expansion valve 16 to the local cooling state again to lower the temperature of the evaporator inlet 10a. In this way, by repeatedly switching the electronic linear expansion valve 16 to linear, the control device maintains the temperature of the evaporator inlet 10a at the inlet set temperature for a predetermined inlet temperature holding time P2.

From time T106 when the temperature of the evaporator inlet 10a reaches the inlet set temperature, at time T108 when a predetermined inlet temperature holding time P2 has elapsed, the control device finally switches the electronic linear expansion valve 16 to the entire cooling state, To maintain. By changing the length of the inlet temperature holding time P2, the initial ice mass amount immediately after the drinking water dispenser 1 starts operation can be controlled.
The subsequent operations are the same as those after time T104 in the first embodiment.

Embodiment 3 FIG.
Embodiment 3 changes the control method of the electronic linear expansion valve 16 in Embodiment 1. FIG. Hereinafter, differences from the first embodiment will be described.
After the electronic linear expansion valve 16 enters the local cooling state at time T102, the control device monitors the temperature of the evaporator outlet 10b detected by the refrigerant outlet temperature sensor 22, and performs a predetermined outlet temperature holding time P3 (for example, 10 minutes). Only) at a predetermined inlet set temperature.
For example, as shown in FIG. 2, when the temperature of the evaporator outlet 10b becomes higher than the outlet set temperature, for example, 10 ° C. at time T110, the control device linearly switches the electronic linear expansion valve 16 to the entire cooling state. As a result, the state in which the evaporator inlet 10a is locally cooled is eliminated, so that the entire evaporator 10 including the evaporator outlet 10b is cooled, and the temperature of the evaporator outlet 10b is lowered to be lower than the outlet set temperature. When the temperature becomes lower than the outlet set temperature, the control device linearly switches the electronic linear expansion valve 16 to the local cooling state again, locally cools the evaporator inlet 10a, and as a result, the temperature of the evaporator outlet 10b increases. Thus, by repeatedly switching the electronic linear expansion valve 16, the control device maintains the temperature of the evaporator outlet 10b at the outlet set temperature for the predetermined outlet temperature holding time P3.

At time T112 when a predetermined outlet temperature holding time P3 has elapsed from time T110 when the temperature of the evaporator outlet 10b has reached the outlet set temperature, the control device finally switches the electronic linear expansion valve 16 to the overall cooling state, To maintain. By changing the length of the outlet temperature holding time P3, the initial ice mass amount immediately after the drinking water dispenser 1 starts operation can be controlled.
The subsequent operations are the same as those after time T104 in the first embodiment.

Embodiment 4 FIG.
The fourth embodiment changes the timing control method for returning the electronic linear expansion valve 16 from the local cooling state to the whole cooling state in the first embodiment.
As shown in FIG. 3, the operation of the drinking water dispenser 1 is started at time T200, the cooling water temperature is reached at time T202, and the electronic linear expansion valve 16 is switched to the local cooling state. The steps so far are the same as in the first embodiment.
The control device operates the electronic linear expansion valve 16 in a locally cooled state until the ice presence / absence sensor 23 detects icing of the cooling water in the portion 10c immediately below the water surface of the evaporator 10. For example, when the ice presence / absence sensor 23 detects icing at time T204, the control device switches the electronic linear expansion valve 16 to the entire cooling state at that time.
The subsequent operations are the same as those after time T104 in the first embodiment.

Embodiment 5 FIG.
In the fifth embodiment, the timing control method for returning the electronic linear expansion valve 16 from the local cooling state to the whole cooling state in the second embodiment is the same as that in the fourth embodiment.
As shown in FIG. 3, the operation of the drinking water dispenser 1 is started at time T200, the cooling water temperature is reached at time T202, and the electronic linear expansion valve 16 is switched to the local cooling state. The steps so far are the same as in the second embodiment.
The controller repeatedly switches the electronic linear expansion valve 16 in the same manner as in the second embodiment until the icing presence / absence sensor 23 detects icing in the portion 10c immediately below the water surface of the evaporator 10, and the temperature of the evaporator inlet 10a is set to the inlet set temperature. maintain. Thereafter, for example, when the ice presence / absence sensor 23 detects icing at time T206, the electronic linear expansion valve 16 is finally switched to the entire cooling state at that time, and the entire cooling state is maintained as it is.

Embodiment 6 FIG.
In the sixth embodiment, the timing control method for returning the electronic linear expansion valve 16 from the local cooling state to the whole cooling state in the third embodiment is the same as that in the fourth embodiment.
As shown in FIG. 3, the operation of the drinking water dispenser 1 is started at time T200, the cooling water temperature is reached at time T202, and the electronic linear expansion valve 16 is switched to the local cooling state. The process up to this point is the same as in the third embodiment.
The control device repeatedly switches the electronic linear expansion valve 16 in the same manner as in the second embodiment until the icing presence / absence sensor 23 detects icing in the portion 10c immediately below the water surface of the evaporator 10, and the temperature of the evaporator outlet 10b is set to the outlet set temperature. maintain. For example, when the ice presence / absence sensor 23 detects icing at time T208, the electronic linear expansion valve 16 is finally switched to the entire cooling state at that time, and the entire cooling state is maintained as it is.

Embodiment 7 FIG.
Embodiment 7 changes the control method of the timing which switches the electronic linear expansion valve 16 from a whole cooling state to a local cooling state in Embodiment 1. FIG.
As shown in FIG. 4, the operation of the drinking water dispenser 1 is started at time T300. The control device monitors the presence / absence of freezing in the portion 10c immediately below the water surface of the evaporator 10 detected by the ice presence / absence sensor 23 and the cooling water temperature detected by the cooling water temperature sensor 24, and there is no freezing and the cooling water temperature. It is determined whether or not the temperature is lower than the set water temperature. The set water temperature may be a value higher than the melting point of the cooling water, but is preferably about 2 ° C. In this example, it is 2 ° C.
For example, at time T302, when there is no freezing and the cooling water temperature is equal to or lower than the set water temperature, the control device switches the electronic linear expansion valve 16 to the local cooling state at that time. As a result, the vicinity of the evaporator inlet 10a is locally cooled, and thereafter, freezing of the portion 10c immediately below the water surface occurs at time T304.

The control device holds the electronic linear expansion valve 16 in the local cooling state for a predetermined cooling time P4 (for example, 20 minutes) from time T302 when the cooling water temperature reaches the set water temperature, and at time T306 when the cooling time P4 has elapsed. Return to total cooling. After time T306, the entire evaporator 10 is cooled substantially uniformly. The cooling time P4 may be a time that can cause icing in the portion 10c immediately below the water surface of the evaporator 10. By changing the length of the cooling time P4, the initial ice mass amount immediately after the drinking water dispenser 1 starts operation can be controlled.
The subsequent operations are the same as those after time T104 in the first embodiment.

After time T306, not all the ice has melted, and the ice presence sensor 23 always detects icing in the portion 10c immediately below the water surface of the evaporator 10, so that the electronic linearity is maintained regardless of the cooling water temperature. The expansion valve 16 remains in the entire cooling state. If, for example, the continuous water injection by the user continues for a long time, the ice melts and the ice presence / absence sensor 23 detects a state where there is no icing, and the cooling water temperature falls below the set water temperature, the above time Control similar to that after T302 is performed.
As described above, according to the seventh embodiment, the drinking water dispenser 1 locally cools the evaporator inlet 10a before the cooling water enters the supercooled state, so that freezing of the portion 10c immediately below the water surface is generated early. . For this reason, it is possible to more reliably avoid a state in which the cooling water is supercooled.

  In the seventh embodiment, the timing at which the electronic linear expansion valve 16 is switched from the local cooling state to the whole cooling state is based on the cooling time P4. May be based on the output of. This control is performed, for example, as shown in FIG. In FIG. 5, the operation of the drinking water dispenser 1 is started at time T400, and the electronic linear expansion valve 16 is switched to the local cooling state at time T402. Thereafter, when the ice presence sensor 23 detects icing in the portion 10c immediately below the water surface of the evaporator 10 at time T404, the control device switches the electronic linear expansion valve 16 to the entire cooling state.

Embodiment 8 FIG.
In the eighth embodiment, the control method for the electronic linear expansion valve 16 is changed in the seventh embodiment. Hereinafter, differences from the seventh embodiment will be described.
As shown in FIG. 4, after the electronic linear expansion valve 16 is in the local cooling state at time T302, the control device monitors the temperature of the evaporator inlet 10a detected by the refrigerant inlet temperature sensor 20, and determines a predetermined inlet temperature. The temperature is maintained at a predetermined inlet set temperature for a holding time P5 (for example, 15 minutes). This control is performed in the same manner as the control at time T106 to T108 in the second embodiment.

  From time T308 when the temperature of the evaporator inlet 10a reaches the inlet set temperature, at time T310 when a predetermined inlet temperature holding time P5 has elapsed, the control device brings the electronic linear expansion valve 16 into the overall cooling state. The inlet temperature holding time P5 may be a time that can cause icing in the portion 10c immediately below the water surface of the evaporator 10. By changing the length of the inlet temperature holding time P5, the initial ice mass amount immediately after the drinking water dispenser 1 starts operation can be controlled.

  In the eighth embodiment, the timing at which the electronic linear expansion valve 16 is finally switched to the overall cooling state is based on the inlet temperature holding time P5. 23 outputs may be used. For example, as shown in FIG. 5, the operation of the drinking water dispenser 1 is started at time T400, the electronic linear expansion valve 16 is switched to the local cooling state at time T402, and the temperature of the evaporator inlet 10a is held at the inlet set temperature. . Thereafter, when the ice presence sensor 23 detects icing in the portion 10c immediately below the water surface of the evaporator 10 at time T406, the control device finally switches the electronic linear expansion valve 16 to the entire cooling state.

Embodiment 9 FIG.
In the ninth embodiment, the control method of the electronic linear expansion valve 16 is changed in the seventh embodiment. Hereinafter, differences from the seventh embodiment will be described.
As shown in FIG. 4, after the electronic linear expansion valve 16 is in the local cooling state at time T302, the control device monitors the temperature of the evaporator outlet 10b detected by the refrigerant outlet temperature sensor 22 to obtain a predetermined outlet temperature. The temperature is maintained at a predetermined inlet set temperature for a holding time P6 (for example, 15 minutes). This control is performed in the same manner as the control at time T110 to T112 in the third embodiment.

  From time T312 at which the temperature of the evaporator outlet 10b reaches the outlet set temperature, at time T314 when a predetermined outlet temperature holding time P6 has elapsed, the control device sets the electronic linear expansion valve 16 to the overall cooling state. The outlet temperature holding time P6 may be a time that can cause icing in the portion 10c immediately below the water surface of the evaporator 10. By changing the length of the outlet temperature holding time P6, the initial ice mass amount immediately after the drinking water dispenser 1 starts operation can be controlled.

  In the ninth embodiment, the timing at which the electronic linear expansion valve 16 is finally switched to the overall cooling state is based on the outlet temperature holding time P6. 23 outputs may be used. For example, as shown in FIG. 5, the operation of the drinking water dispenser 1 is started at time T400, the electronic linear expansion valve 16 is switched to the local cooling state at time T402, and the temperature of the evaporator outlet 10b is held at the outlet set temperature. . Thereafter, when the ice presence / absence sensor 23 detects icing in the portion 10c immediately below the water surface of the evaporator 10 at time T408, the control device finally switches the electronic linear expansion valve 16 to the entire cooling state.

Embodiment 10 FIG.
The tenth embodiment changes the control method of the electronic linear expansion valve 16 in the first embodiment. Hereinafter, differences from the first embodiment will be described.
The control device controls the electronic linear expansion valve 16 based on the output of the ice presence / absence sensor 23. When the ice presence / absence sensor 23 detects a state in which the portion 10c immediately below the water surface of the evaporator 10 is not frozen, the control device places the electronic linear expansion valve 16 in the local cooling state. When the ice presence / absence sensor 23 detects that the portion 10c immediately below the water surface of the evaporator 10 is frozen, the control device sets the electronic linear expansion valve 16 to the entire cooling state.

For example, as shown in FIG. 6, immediately after the operation of the drinking water dispenser 1 is started at time T500, the ice presence / absence sensor 23 detects a state in which the ice is not frozen. Let it cool.
Thereafter, when the ice presence sensor 23 detects icing at time T502, the control device switches the electronic linear expansion valve 16 to the entire cooling state.
The subsequent operations are the same as those after time T104 in the first embodiment.

  In addition, after time T502, not all the ice has melted and the ice presence sensor 23 always detects icing in the portion 10c immediately below the water surface of the evaporator 10, so the electronic linear expansion valve 16 is cooled as a whole. The state remains. If the ice melts and the ice presence / absence sensor 23 detects no icing due to continuous water injection by the user for a long time, the same control as that after time T500 is performed.

Embodiment 11 FIG.
In the eleventh embodiment, the control method of the electronic linear expansion valve 16 is changed in the tenth embodiment. Hereinafter, differences from the tenth embodiment will be described.
The control device controls the electronic linear expansion valve 16 based on the output of the ice presence / absence sensor 23. When the ice presence / absence sensor 23 detects that the portion 10c immediately below the water surface of the evaporator 10 is not frozen, the control device controls the electronic linear expansion valve 16 so as to maintain the temperature of the evaporator inlet 10a at the inlet set temperature. . When the ice presence / absence sensor 23 detects that the portion 10c immediately below the water surface of the evaporator 10 is frozen, the control device sets the electronic linear expansion valve 16 to the entire cooling state.

For example, as shown in FIG. 6, immediately after the operation of the drinking water dispenser 1 is started at time T500, the ice presence / absence sensor 23 detects a state in which the ice is not frozen. Let it cool.
Thereafter, when the temperature of the evaporator inlet 10a reaches the inlet set temperature, the control device maintains the temperature in the same manner as in the second embodiment.
Thereafter, when the ice presence sensor 23 detects icing at time T504, the control device finally switches the electronic linear expansion valve 16 to the entire cooling state.

Embodiment 12 FIG.
The twelfth embodiment changes the control method of the electronic linear expansion valve 16 in the tenth embodiment. Hereinafter, differences from the tenth embodiment will be described.
The control device controls the electronic linear expansion valve 16 based on the output of the ice presence / absence sensor 23. When the ice presence / absence sensor 23 detects that the portion 10c immediately below the water surface of the evaporator 10 is not frozen, the control device controls the electronic linear expansion valve 16 so as to maintain the temperature of the evaporator outlet 10b at the outlet set temperature. . When the ice presence / absence sensor 23 detects that the portion 10c immediately below the water surface of the evaporator 10 is frozen, the control device sets the electronic linear expansion valve 16 to the entire cooling state.

For example, as shown in FIG. 6, immediately after the operation of the drinking water dispenser 1 is started at time T500, the ice presence / absence sensor 23 detects a state in which the ice is not frozen. Let it cool.
Thereafter, when the temperature of the evaporator outlet 10b reaches the outlet set temperature, the control device maintains the temperature in the same manner as in the third embodiment.
Thereafter, when the ice presence sensor 23 detects icing at time T506, the control device finally switches the electronic linear expansion valve 16 to the entire cooling state.

It is a figure which shows the structure of the drinking water dispenser 1 which concerns on this invention. It is a figure which shows the operation | movement which concerns on Embodiment 1-3 of the drinking water dispenser 1 which concerns on this invention. It is a figure which shows the operation | movement which concerns on Embodiment 4-6 of the drinking water dispenser 1 which concerns on this invention. It is a figure which shows the operation | movement which concerns on Embodiment 7-9 of the drinking water dispenser 1 which concerns on this invention. It is a figure which shows the operation | movement which concerns on each modification of Embodiment 7-9 of the drinking water dispenser 1 which concerns on this invention. It is a figure which shows the operation | movement which concerns on Embodiment 10-12 of the drinking water dispenser 1 which concerns on this invention. It is a figure which shows the structure of the conventional drinking water dispenser 140. FIG. It is a figure which shows operation | movement of the conventional drinking water dispenser 140. FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Drinking water dispenser, 6 Cooling water tank, 10 Evaporator, 10a Predetermined part (evaporator inlet), 23 icing detection means (ice presence sensor), 24 Cooling water temperature detection means (cooling water temperature sensor).

Claims (4)

A cooling water tank for storing cooling water for cooling drinking water;
A refrigeration apparatus including an evaporator for cooling the cooling water;
With
The refrigeration apparatus includes an electronic linear expansion valve that expands the refrigerant, and the electronic linear expansion valve varies a circulation amount of the refrigerant according to an opening degree of the electronic linear expansion valve,
The electronic linear expansion valve controls the degree of opening of the electronic linear expansion valve to more uniformly cool the entire evaporator, and provides an overall cooling state and more locally a predetermined value on the expansion valve side of the evaporator. It is possible to switch to local cooling state, cooling the part,
A cooling water temperature detecting means for detecting a cooling water temperature;
When the coolant temperature detected by the coolant temperature detection means is equal to or lower than a predetermined water temperature set below the melting point of the coolant, the electronic linear expansion valve is switched to the local cooling state, and then when the predetermined time has elapsed, the electronic linear expansion valve that is switched to the entire cooling state
Drinking water dispenser. A cooling water tank for storing cooling water for cooling drinking water;
A refrigeration apparatus including an evaporator for cooling the cooling water;
With
The refrigeration apparatus includes an electronic linear expansion valve that expands the refrigerant, and the electronic linear expansion valve varies a circulation amount of the refrigerant according to an opening degree of the electronic linear expansion valve,
The electronic linear expansion valve controls the degree of opening of the electronic linear expansion valve to more uniformly cool the entire evaporator, and provides an overall cooling state and more locally a predetermined value on the expansion valve side of the evaporator. It is possible to switch to local cooling state, cooling the part,
Cooling water temperature detecting means for detecting the temperature of the cooling water;
Icing detection means for detecting whether or not the cooling water is frozen in the vicinity of the predetermined portion on the expansion valve side of the evaporator,
When the coolant temperature detected by the coolant temperature detection means is equal to or lower than a predetermined water temperature set below the melting point of the coolant, the electronic linear expansion valve is switched to the local cooling state, and then when the icing detection means detects the icing of the coolant, the electronic linear expansion valve that is switched to the entire cooling state
Drinking water dispenser. A cooling water tank for storing cooling water for cooling drinking water;
A refrigeration apparatus including an evaporator for cooling the cooling water;
With
The refrigeration apparatus includes an electronic linear expansion valve that expands the refrigerant, and the electronic linear expansion valve varies a circulation amount of the refrigerant according to an opening degree of the electronic linear expansion valve,
The electronic linear expansion valve controls the degree of opening of the electronic linear expansion valve to more uniformly cool the entire evaporator, and provides an overall cooling state and more locally a predetermined value on the expansion valve side of the evaporator. It is possible to switch to local cooling state, cooling the part,
Cooling water temperature detecting means for detecting the temperature of the cooling water;
Icing detection means for detecting whether or not the cooling water is frozen in the vicinity of the predetermined portion on the expansion valve side of the evaporator,
When the cooling water temperature detected by the cooling water temperature detecting means is not more than a predetermined set water temperature and the icing detection means detects that the cooling water is not frozen, the electronic linear expansion valve is locally is switched to the cooling condition, then, when a predetermined time has elapsed, the electronic linear expansion valve that is switched to the entire cooling state
Drinking water dispenser. A cooling water tank for storing cooling water for cooling drinking water;
A refrigeration apparatus including an evaporator for cooling the cooling water;
With
The refrigeration apparatus includes an electronic linear expansion valve that expands the refrigerant, and the electronic linear expansion valve varies a circulation amount of the refrigerant according to an opening degree of the electronic linear expansion valve,
The electronic linear expansion valve controls the degree of opening of the electronic linear expansion valve to more uniformly cool the entire evaporator, and provides an overall cooling state and more locally a predetermined value on the expansion valve side of the evaporator. It is possible to switch to local cooling state, cooling the part,
Cooling water temperature detecting means for detecting the temperature of the cooling water;
Icing detection means for detecting whether or not the cooling water is frozen in the vicinity of the predetermined portion on the expansion valve side of the evaporator,
When the cooling water temperature detected by the cooling water temperature detecting means is not more than a predetermined set water temperature and the icing detection means detects that the cooling water is not frozen, the electronic linear expansion valve is locally is switched to the cooling condition, then, when the icing detection means detects the icing of the coolant, the electronic linear expansion valve that is switched to the entire cooling state
Drinking water dispenser.

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