JP5187028B2 - Water server - Google Patents

Description

  The present invention relates to a water server that can supply at least warm water (hot water) as drinking water by receiving water replenished in a container such as a water bottle and heating the heater, and in particular, the water server can be re-installed at the time of installation or after draining water. The present invention relates to a technique for avoiding the occurrence of a situation where a heater is heated even though there is no water to be heated at the time of use.

  Conventionally, a water server is also referred to as a “dispenser”, and water is supplied to a built-in tank from a water bottle that is replaceably mounted, and this is cooled and maintained in a cold water state by a user lever operation or cock operation. Some supply cold water for drinking. Moreover, what can supply not only cold water but warm water is also provided. That is, the water is stored in a hot water tank provided separately from the cold water tank, and the water is heated by a heater and kept at a predetermined temperature, and hot water (hot water) is supplied by a user's lever operation or cock operation as described above. What is supplied for drinking is provided.

  Patent Document 1 describes the following points as a technique for preventing air from entering an internal pipe or a built-in tank in such a water server. That is, a spherical float stopper and a valve seat on which the float stopper settles and contacts are provided in the connection portion of the water bottle, and when the water is dropped downward from the water bottle, the float stopper is buoyant. Allow water to drop away from the water, and when the water in the water bottle is consumed and lost, it settles down and comes into contact with the valve seat so that air does not enter the piping or the built-in tank. It is described to do.

  Patent Document 2 describes means for detecting a water level at a predetermined level position. That is, it is described that a float switch is installed at a predetermined level position in the hot water tank that can be heated by the heater so that the float switch can detect that the water level in the hot water tank has increased or decreased to the predetermined level position. Has been.

JP 2005-308297 A JP 11-46981 A

  By the way, when installing a new water server, or when reusing a water server that has been stored in a state where water has been drained from the inside due to the end of the rental period, etc., the internal hot water tank is substantially When it is empty, it is necessary to air purge the inside and draw water to be heated. If the heater is heated without performing the air purge, the hot water tank falls into an empty state, and this must be avoided. Heating of the heater is normally started automatically when a water bottle is attached and the power switch or the like is turned on. Therefore, there is a possibility that the above-mentioned emptying occurs due to human error.

  As a countermeasure, it is conceivable to install an air vent pipe upward from the hot water tank. That is, the air in the hot water tank is pushed out from the air vent pipe by the water head pressure from the water bottle. However, during normal hot water supply operation, not only the hot water tank but also the air vent pipe is filled with hot water, so that heat is radiated from the outer peripheral surface of the air vent pipe. As a result, the heater needs to be heated by an amount corresponding to the heat radiation, resulting in unnecessary power consumption for the heater heating.

  On the other hand, in order to detect that the inside of the hot water tank is empty or is in a state close to the sky that causes the same state as that of emptying although there is water, it is necessary to newly add a sensor for that purpose. In addition, even if the user or the worker recognizes that the air purge is necessary, the air purge work requires work that depends on intuition by manual operation.

  The present invention has been made in view of such circumstances, and the object of the present invention is to reliably determine whether or not air purge is necessary, and to reliably perform air purge when necessary. An object of the present invention is to provide a water server that can reliably avoid the occurrence of airing by allowing the heater to be heated.

  In order to achieve the above object, according to the first aspect of the present invention, there is provided a warm water tank configured to be constituted by a sealed container and receiving water supplied by a head difference from a water source container installed at a higher level, and the water in the warm water tank is heated to A heater that generates water, an open / close control valve that draws hot water from the hot water tank so as to be openable and closable and supplies the water to the outside, a water detection sensor that detects whether water or hot water is present in the hot water tank, And control means for controlling the operation based on the output from the water detection sensor. And as said control means, when receiving an ON output from an operation switch for generating hot water, it is determined whether there is water or hot water in the hot water tank based on a detection signal from the water detection sensor, When it is determined that there is no water or hot water, the heating operation by the heater is prohibited, the open / close control valve is opened and the inside of the hot water tank is air purged, and water is poured from the water source container into the hot water tank along with the air purge. Then, the heating operation by the heater is permitted (Claim 1).

  In the case of the first invention, it is possible to reliably determine whether or not the state in the hot water tank is in a state that requires air purge based on the detection of whether or not water is present. When necessary, it is possible to perform air purge surely and in a timely manner by automatic processing by the opening / closing control of the opening / closing control valve by the control means without manual operation by the user. The automatic air purge process allows water to be poured into the hot water tank to allow the heater to be heated after it is full or at a predetermined water level. Can be planned.

  As the water detection sensor in the present invention, a self-heating type thermistor can be used that can detect whether or not water is present due to a temperature change during self-heating in addition to temperature detection. ). By doing in this way, it becomes possible to perform both normal temperature detection in the hot water tank and detection of presence / absence of water for determining whether or not air purge is required, with one sensor, It can eliminate the need for special equipment for water detection.

In the second invention, a warm water tank that is configured by a sealed container and receives water from a water source container installed at a higher position by a head difference, a heater that heats the water in the warm water tank to generate warm water, and the warm water An open / close control valve that draws warm water from the tank so that it can be switched between open and close, and a temperature / water detection sensor that detects whether there is water due to temperature changes during self-heating in addition to detecting the water temperature in the hot water tank And control means for controlling the operation based on the output from the temperature / water detection sensor. Then, as the control means, upon receiving a ON output from the operation switch for generating hot water, warm water is within the hot water tank on the basis of a comparison between the detected temperature and determine the temperature from the temperature and water detection sensor When the determination is other than the determination that there is hot water, the heating operation by the heater is prohibited, and it is further determined whether there is water in the hot water tank by the temperature / water detection sensor. When it is determined that there is no water, the heating control by the heater is prohibited and the open / close control valve is opened to purge the inside of the hot water tank, and water is poured from the water source container into the hot water tank along with the air purge. In the above, the heating operation by the heater is permitted (claim 3).

In 3rd invention, the warm water tank which receives supply of water by the water head difference from the water source container comprised by the sealed container and installed in the upper rank, the heater which heats the water in this warm water tank, and produces | generates warm water, The said warm water An open / close control valve that draws warm water from the tank so that it can be switched between open and close, and a temperature / water detection sensor that detects whether there is water due to temperature changes during self-heating in addition to detecting the water temperature in the hot water tank And control means for controlling the operation based on the output from the temperature / water detection sensor. Then, as the control means, when the output condition of the heater request is a request command for heating operation by the heater is established, in the hot water tank on the basis of a comparison between the detected temperature and determine the temperature from the temperature and water detection sensor a determination is made whether temperature water is present, also prohibits the heating operation by the heater as an upper Kihi over data heating request is output when the determination of non-determination of the hot water there, further the temperature and The water detection sensor determines whether or not there is water in the hot water tank. If it is determined that there is no water, the heating control by the heater is prohibited and the open / close control valve is switched to open the hot water tank. The air purging is performed, and water is poured from the water source container into the hot water tank along with the air purging, and then the heating operation by the heater is permitted (claim 4).

  In the case of the second invention or the third invention, whether or not the air purge is necessary is determined based on the detected temperature based on whether or not the hot water is present, and it is determined that the hot water is surely present. Except for, the presence / absence of water is determined and the above air purge is determined to determine whether it is necessary. Therefore, if hot water is present in the hot water tank, its presence is easily detected. Will be able to. And since it is made to detect the presence / absence of water only when it is unclear whether or not there is water only by temperature detection, energy saving and labor saving are achieved in terms of control. In addition, when there is no water and air purge is required, it is possible to perform air purge reliably and timely by automatic processing by opening / closing control of the open / close control valve by the control means without manual operation by the user. Become. The automatic air purge process allows water to be poured into the hot water tank to allow the heater to be heated after it is full or at a predetermined water level. Can be planned. In particular, in the case of the third invention, for example, when the operation switch is turned ON and it is detected that hot water has been drained from the hot water tank, there is a condition under which the heater should be heated during the warm water keeping operation control in the hot water tank. Automatic air purge based on the presence or absence of water when a heater heating request output condition is established, such as when the heater heating operation for forcibly boiling water in the hot water tank is performed It is judged whether or not it is in a state that requires treatment, and if necessary, monitoring control is performed to avoid the occurrence of an empty state in which the heater is allowed to be heated after water is poured into the hot water tank by automatic air purge processing. Can be executed. This ensures that even when there is a possibility of water injection by air purge, even if the monitoring switch is executed by receiving the ON output of the operation switch, it is detected and water is injected by automatic air purge processing. Thus, it is possible to reliably avoid the possibility of the occurrence of an empty-running state.

  As a temperature / water detection sensor in the second or third invention, a self-heating type thermistor is used. In addition to temperature detection by energizing a normal power source, self-heating is performed by switching energization to a power source for water detection. It can be configured to be able to detect whether or not water is present due to a change in temperature with time. By doing in this way, it becomes possible to perform both normal temperature detection in the hot water tank and detection of presence / absence of water for determining whether or not air purge is required, with one sensor, It can eliminate the need for special equipment for water detection. Moreover, as to whether or not there is water, first, the presence / absence of hot water is determined by temperature detection, and then the water detection power supply is switched to the presence / absence of water only when necessary. For this reason, it is possible to maintain the performance of the apparatus for a long time from the viewpoint of durability by limiting the frequency of energization switching. In addition, first, the presence / absence of hot water is determined by temperature detection, and at least when there is no hot water, the presence / absence of water is determined by switching the power supply to the water detection power supply. In a high-temperature region where water detection due to self-heating does not appear so clearly, that is, when the temperature change is small even if self-heating is performed, it is determined by temperature detection instead of water detection due to self-heating. In the low-temperature region, that is, when the temperature change after self-heating is large, water detection by self-heating can be performed. As a result, the occurrence of erroneous determination in the high temperature region can be reliably avoided.

  As described above, according to the water server of claim 1 or claim 2, whether or not the state in the hot water tank is in a state that requires air purge is reliably determined based on the detection of whether or not there is water. If there is no water and air purge is required, the air purge should be performed automatically and timely by automatic control by the opening / closing control valve opening / closing control by the control means without manual operation by the user. Will be able to. In addition, this automatic air purge process allows water to be poured into the hot water tank to allow the heater to be heated after it is full or at a predetermined water level. It will be possible to improve.

  In particular, according to claim 2, it is possible to perform both normal temperature detection in the hot water tank and detection of presence / absence of water for determining whether or not air purge is required, with one sensor, It is possible to eliminate the need for special equipment for water detection.

  According to the water server of any one of claims 3 to 5, the presence or absence of water is determined only when the presence of warm water is first determined by temperature detection and it is unclear whether or not there is water only by temperature detection. Therefore, it is possible to achieve energy saving and labor saving in control in detection control for grasping whether or not air purge is necessary. In addition, when there is no water and air purge is required, the air purge can be performed reliably and timely by automatic processing by the open / close control control of the open / close control valve by the control means without the user's manual operation. become. In addition, this automatic air purge process allows water to be poured into the hot water tank to allow the heater to be heated after it is full or at a predetermined water level. It will be possible to improve.

  In particular, according to the fourth aspect of the present invention, detection control for grasping whether or not air purge is necessary is received in response to the ON output of the operation switch, and automatic air purge processing is performed when there is no water and air purge is necessary. Even when the monitoring control is not executed, if there is a possibility that water injection by air purge may be required, it will be detected reliably and water will be injected by automatic air purge processing to ensure that there is a possibility of occurrence of an empty fired state. It will be possible to avoid.

  Further, according to the fifth aspect, it is possible to perform both normal temperature detection in the hot water tank and detection of presence / absence of water for determining whether or not air purge is necessary with a single sensor. This eliminates the need for special equipment for water detection. In addition, whether water is present or not is first determined by detecting the presence or absence of hot water, and then only when necessary, the water detection power supply is switched to determine the presence or absence of water. For this reason, it is possible to maintain the performance of the device for a long time from the viewpoint of durability by limiting the frequency of energization switching. In addition, it is possible to reliably avoid the possibility of misjudgment in high temperature areas where water detection due to self-heating does not appear so clearly, and detection of presence / absence of water is more reliably performed. Can be realized.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows an apparatus configuration of a water server according to an embodiment of the present invention, and FIG. 2 shows an example of an external configuration of the water server. In both figures, reference numeral 1 denotes an outer housing, 2 (shown only in FIG. 1) is a cold water tank, and 3 is detachably mounted on the upper side of the cold water tank 2 to serve as a water supply source to the cold water tank 2. A water bottle as a water source container, 4 (appears only in FIG. 1) is a refrigeration circuit for cooling the water in the cold water tank 2, and 5 (appears only in FIG. 1) is hot water that receives water supply through the cold water tank 2 A tank, 6 (appears only in FIG. 1) is a heater for heating the water in the hot water tank 3, and 7 (appears only in FIG. 1) is a controller as control means for controlling the operation of the water server.

  A connecting recess 11 for attaching the water bottle 3 is formed in the central portion of the upper surface of the housing 1. This connection recessed part 11 is provided with the communicating cylinder part 12 which protrudes upwards along the central axis while it has the inner surface shape which can be fitted in the state which reversed the neck part 31 of the water bottle 3 upside down. By inserting the neck portion 31 from the top to the bottom with the water bottle 3 upside down with respect to the connecting recess 11, the communicating tube portion 12 is inserted upward into the neck portion 31 of the water bottle 3, so that the water The water bottle 3 and the cold water tank 2 are connected to each other with the bottle 3 and the cold water tank 2 being in communication with each other. A cup storage 13 for receiving two kinds of drinking water and cold water is formed in the middle position on the front surface of the housing 1 (see FIG. 2). The cold water is located above the cups 81 and 82 of the cup storage 13. And each discharge port 271 and 521 (refer FIG. 1) is arrange | positioned. Further, a cold water switch 14 for taking out cold water and a hot water switch 15 for taking out hot water are disposed in front of the upper position of the cup storage 13.

  The cold water tank 2 is a container opened upward, and a lid 21 that also serves as a light shielding plate is fitted into the upper end opening of the container via a packing or the like and sealed. A substantially central portion of the lid 21 is a concave portion 22 that can be externally fitted to the connecting concave portion 11, and a through hole that communicates with the communicating cylinder portion 12 is formed at the central position of the concave portion 22. Further, a baffle plate 23 extending in the horizontal direction is disposed at a predetermined level position in the cold water tank 2, and a connecting pipe 24 is connected so that the upstream end is open to the center position of the baffle plate 23. The downstream end of the connection pipe 24 communicates with the bottom of the hot water tank 5. A cold water intake pipe 26 is extended from the reservoir 25 at the bottom of the cold water tank 2 to a position above the cup storage 13 of the housing 1, and a cold water intake valve 27 installed on the downstream end side of the cold water intake pipe 26 is opened. When operated, the cold water in the cold water tank 2 is discharged from the discharge port 271. This cold water intake valve 27 is constituted by an electromagnetic open / close control valve, and is normally maintained in a closed state, and is opened and closed by a control signal from the controller 7. Further, germicidal lamps 28 and 29 are installed in the cold water tank 2 so that the cold water can be sterilized while being stored inside by the germicidal lamps 28 and 29. The lower end of one of the germicidal lamps 28 is extended into the reservoir 25 so that it can illuminate the inside of the cold water intake pipe 26.

  The water bottle 3 is also referred to as a “gallon bottle” and is provided in a state in which drinking water is filled and contained therein. And this water bottle 3 is mounted | worn with respect to a water server as mentioned above, and whenever the drinking water in the mounted water bottle 3 is consumed and it becomes empty, it is exchanged for the new water bottle 3. .

  The refrigeration circuit 4 includes a cooling pipe 42 constituting an evaporator on a circulation path 41 in which a refrigerant is sealed. The cooling pipe 42 is wound around the cold water tank 2, and the refrigerant compressed by the compressor 43 is radiated by the radiator 44 to be liquefied. It takes heat from the water and cools it.

  The hot water tank 5 is a hermetic container disposed below the cold water tank 2, and therefore below the water bottle 3, and has a heater 6 disposed therein. Water is poured into the hot water tank 5 from the inside of the cold water tank 2 (or the water bottle 3) through the connecting pipe 24 based on the water head difference, and the hot water tank 5 is replenished by the amount reduced by the water intake. Accordingly, when viewed from the hot water tank 5, not only the water bottle 3 but also the cold water tank 2 constitutes a water source container. Further, a hot water intake pipe 51 is extended from the top of the hot water tank 5 to a position above the cup storage place 13 of the housing 1, extended to the hot water discharge port on the front surface thereof, and provided at the downstream end side of the hot water intake pipe 51. When the warm water intake valve 52 is opened, the warm water in the warm water tank 5 is discharged from the discharge port 521. The hot water intake valve 52 is also constituted by an electromagnetic opening / closing control valve, like the cold water intake valve 27, and is normally maintained in a closed state, and is opened and closed by a control signal from the controller 7. . Reference numeral 241 in FIG. 1 is a drain pipe, which drains from the connection pipe 24 and extends to the housing 1, and is connected to the inside of the cold water tank 2 from the downstream connection port. The cold water and the hot water in the hot water tank 5 can be discharged to drain water from the water server.

  The hot water tank 5 is provided with an overheat prevention device 53 and a temperature / water detection sensor 54. The overheat prevention device 53 is configured to cut off the energization of the heater 6 by detecting a temperature immediately before boiling (for example, 95 ° C.) using a bimetal. The temperature / water detection sensor 54 is constituted by a self-heating type thermistor, and in addition to detecting the temperature of the hot water in the hot water tank 5, it can also detect whether there is water (water detection). That is, when self-heating is caused by energization, if there is no water, the self-heating is only dissipated in the air, while if water is present, heat is quickly deprived even if self-heating occurs. For this reason, the presence / absence of water can be detected based on how the temperature is lowered when the self-heat is generated. The temperature drop during the self-heating is detected by a change in the resistance value of the resistor of the self-heating thermistor to detect the presence of water. Such switching of the function of water detection and temperature detection is performed by switching of the energized power source. That is, for example, DC5V is used for temperature detection, and DC15V is used for detection of water, for example, by switching the power supply to be energized. In addition, a normal power source for detecting temperature of DC5V is always set, and when performing water detection, it is switched to DC15V for water detection. When it is detected that there is water by the presence / absence detection by the temperature / water detection sensor 54, the water level is equal to or higher than the level position where the temperature / water detection sensor 54 is installed.

  The controller 7 supplies power to electrically driven elements such as the heater 6, controls related to the cooling operation by the refrigeration circuit 4 and the heating operation by the heater 6, and cold water or hot water based on the output from the cold water switch 14 or the hot water switch 15. In addition to the execution of the control related to the supply operation, the following monitoring control is executed. In other words, this monitoring control is aimed mainly at avoiding the occurrence of airing that the heating by the heater 6 is executed even though there is no water in the hot water tank 5. Based on the temperature detection and presence detection of the hot water in the hot water tank 5 using the water detection sensor 54, based on the monitoring / determination as to whether or not the heating operation by the heater 6 is permitted and the detection of the absence of water. An automatic air purge process and a water injection process to the hot water tank 5 by this automatic air purge process are executed.

  The control related to the cooling operation by the refrigeration circuit 4 and the heating operation by the heater 6 is started when the power is turned on and the water server is used. After cooling or heating to a predetermined temperature, a constant cold water temperature or hot water is supplied. The heat insulation operation is performed so as to maintain the temperature. As the warm water temperature keeping operation control, based on the temperature detection output from the temperature / water detection sensor 54 switched to temperature detection, for example, when the temperature is raised to 90 ° C., the heater 6 is cut off and the heater heating is stopped. On the other hand, when the temperature is lowered to, for example, 80 ° C. by stopping heating, the heater 6 is restarted by resuming energization of the heater 6 so that the temperature of the hot water is kept within a certain range.

  The cold water or hot water supply operation control is performed while the water server is continuously used. When the user turns on the cold water switch 14, the cold water intake valve 27 is opened and cold water is discharged from the cold water tank 2. Alternatively, if the user turns on the hot water switch 15, the hot water intake valve 52 is opened and the hot water is discharged from the hot water tank 5.

  As shown in FIG. 3, the monitoring control is performed by turning on an operation switch which is a precondition for starting heater heating (ON of a power switch or an operation switch after turning on a power switch; a power switch and an operation switch are First, the power supply to the temperature / water detection sensor 54 is switched to the normal power supply (DC5V) or the normal power supply is confirmed (step S1), and the temperature is Based on the temperature detection output from the water detection sensor 54, it is determined whether or not the current detection temperature is equal to or higher than a predetermined determination temperature (for example, 40 ° C.) (step S2). As the determination temperature, if it is equal to or higher than this determination temperature, the hot water tank 5 is cooled, but hot water is surely present. If it is lower than the determination temperature, there is no hot water, but water may be present. A temperature value that can be determined to be in an unknown state such as air or air may be set. If the detected temperature is equal to or higher than the determination temperature (YES in step S2), it can be determined that hot water is reliably present in the hot water tank 5, and therefore the heater 6 is energized to the control unit related to the heating operation control. Permitted (step S3), and thereafter, shifts to normal control.

  If the detected temperature is lower than the determination temperature in step S2 (NO in step S2), it is unknown whether or not there is water, so whether or not there is water by switching to detection of water (air is not present). Check if it is. First, after storing the detected temperature (step S4), the circuit for switching the energization power source for the temperature / water detection sensor 54 to the one for detecting water (DC15V) (step S5) is performed. (Step S6). If it is determined that there is water based on the presence / absence detection output from the temperature / water detection sensor 54 (YES in step S6), the process proceeds to the above step S3 to allow the heater 6 to be energized while the temperature / water detection is performed. If it is determined that there is no water based on the presence detection output from the sensor 54 (NO in step S6), an air purge process and a water injection process associated therewith are performed (steps S7 to S9).

  Here, whether or not there is water based on the presence / absence detection output from the temperature / water detection sensor 54 is determined as follows. DC15V is applied, for example, for 10 seconds from the energized power source switched in step S5 to cause self-heating. The application of DC 15V is stopped, the energizing power source is switched to DC 5V (for temperature detection), and the temperature after self-heating is detected. Then, the detected temperature after self-heating (detected temperature when DC15V application is stopped) is compared with the temperature before self-heating (detected temperature stored in step S4). If it is less than 0 ° C., it cannot be determined that there is water, so the energized state of the heater 6 is not permitted and the prohibited state is maintained. Continue processing. That is, after the application of DC 15 V is stopped, the average value (0.3, 0.4) of the detected temperature at a plurality of times when a predetermined time has elapsed (for example, when 0.3 seconds, 0.4 seconds, and 0.5 seconds have elapsed). , The average value of the detected temperatures for three times at the time when 0.5 seconds have elapsed) is equal to or lower than the water presence determination temperature, it is determined (detected) that there is water. As the water content determination temperature, a temperature value obtained by subtracting a predetermined temperature value α from the detected temperature after self-heating (detected temperature after self-heating -α) is used. Conversely, if it is higher than the water content determination temperature, it is determined that there is no water, and the air purge process and the water injection process associated therewith are performed. In short, both of the fact that a temperature rise of 4 ° C. has occurred due to self-heating due to the application of DC 15 V and that the temperature change within the lapse of a minute time since the application stop of DC 15 V is less than a predetermined temperature value (α) Upon establishment, it is determined (detected) that there is water.

  If it is determined in step S6 that there is no water (NO in step S6), the hot water intake valve 52 is opened and air purge is performed (step S7). When the hot water intake valve 52 is switched to open, the inside of the hot water tank 5 is opened to the atmosphere, so that water is dropped from the side of the water bottle 3 and the cold water tank 2 through the connection pipe 24 by gravity. With this dropped water, the air in the hot water tank 5 is pushed out and air purged, and water is injected into the inside. The air purge is continued until the inside of the hot water tank 5 becomes full or a predetermined water level by this water injection (NO in step S8). The determination of the full water level or the predetermined water level state is changed to detection that there is water by the temperature / water detection sensor 54, and the water level rises from the installation level position of the temperature / water detection sensor 54 to the full water level. This is performed by satisfying the condition that the time tg that would be required has elapsed. If these conditions are satisfied (YES in step S8), the hot water intake valve 52 is returned to the closed state to end the air purge process and the water injection process (step S9), and the temperature / water detection sensor 54 is used for normal temperature detection. After switching (step S10), energization of the heater 6 is permitted (step S3). Thereafter, the water in the hot water tank 5 is heated to a predetermined temperature by heating the heater and kept in a predetermined temperature range. In this state, the hot water is discharged and supplied by the ON operation of the hot water switch 15 by the user.

  In the case of the above embodiment, whether or not there is water in the hot water tank 5 can be reliably detected by the temperature / water detection sensor 54, and it is installed with special equipment such as a water level electrode and a float switch. Without using a thermistor for temperature detection. Also, unlike temperature detection, detection of whether water is present (switching of energized power supply) is performed only when necessary, not constantly monitoring or intermittent monitoring. The performance of the device can be maintained. In this regard, the determination that the hot water is surely present is made based on the temperature detection (YES in step S2), and only when there is no hot water depending on the temperature detection but it is unknown whether there is water or not. In addition, since the presence / absence of water is detected / determined by switching the energized power source, further improvement can be achieved from the viewpoint of durability. Then, based on the detection of whether or not there is water, it is possible to reliably determine whether or not the state in the hot water tank 5 is in a state where air purge is necessary. Accordingly, it is possible to carry out the operation reliably and in a timely manner by the automatic air purge process using the hot water intake valve 52 constituted by the electromagnetic open / close control valve. By this automatic air purge process, water can be poured into the hot water tank 5 to allow the heater to be heated after the water is full or at a predetermined water level, and it is possible to reliably avoid the occurrence of an empty fired state and improve safety. Can do.

<Other embodiments>
In addition, this invention is not limited to the said embodiment, Various other embodiments are included. That is, in the said embodiment, although the example provided also with the cold water tank 2 other than the hot water tank 5 was shown, this invention is not limited to this, If it is a water server comprised including the hot water tank 5 at least, Can be applied. In this case, water may be poured directly from the water bottle into the hot water tank. In addition to the above-described embodiment, the connection state of the connection pipe 24 may be changed to an arrangement state in which the connection pipe 24 is connected to the hot water tank 5 through the outside of the cold water tank 2, for example.

  In the above embodiment, the monitoring control (see FIG. 3) is started by turning on an operation switch such as turning on a power switch or turning on an operation switch, which is a premise for starting heater heating. Not limited to this, the monitoring control may be executed when an output condition of a heating operation request command (heater heating request) by the heater 6 is satisfied. As a case where the output condition of the heater heating request is satisfied, there are the following cases. That is, when drainage by the drainage pipe 241 is detected while the operation switch (power switch or operation switch) is ON, when the condition for turning on the heater 6 during the heat insulation operation control is satisfied, or forced In some cases, a boiling operation is executed. As the detection of the water drainage, the temperature / water detection sensor 54 continues to detect the temperature of the hot water in the hot water tank 5, and a rapid temperature drop (for example, from 80 ° C. to 20 ° C. within a predetermined time). What is necessary is just to determine with the draining having occurred when the fall to etc. is detected.

  In the above embodiment, the heater 6 that is heated by energization is shown as a heater for generating hot water. However, the heater 6 is not limited to this, and is heated by a combustion operation using a heater that is heated by combustion. Heating may be stopped.

  In the above embodiment, the temperature / water detection sensor 54 capable of both temperature detection and water detection is used. However, the present invention is not limited to this, and a water detection sensor may be provided separately from the normal temperature detection sensor. . In this case, water level electrodes and float switches are used to detect the presence / absence of water based on detection signals from these, and if there is no water, heater heating is prohibited and automatic air purge processing and accompanying water injection processing are performed. After that, heater heating may be permitted.

It is a schematic diagram which shows embodiment of this invention. It is a perspective view which shows the example of the external appearance of the water server to which embodiment is applied. It is a flowchart about supervisory control.

Explanation of symbols

3 Water bottle (water source container)
5 Hot water tank 6 Heater 7 Controller (control means)
52 Hot water intake valve (open / close control valve)
54 Temperature / Water Detection Sensor (Water Detection Sensor)

Claims (5)

A warm water tank that is configured by a sealed container and receives water supply from the water source container installed at the upper level by a head difference, a heater that heats the water in the warm water tank to generate warm water, and switches the warm water from the warm water tank to open and close An open / close control valve for taking water as much as possible and supplying it to the outside, a water detection sensor for detecting whether or not there is water or hot water in the hot water tank, and a control means for controlling the operation based on an output from the water detection sensor; With
When the control means receives an ON output from an operation switch for generating hot water, it determines whether there is water or hot water in the hot water tank based on a detection signal from the water detection sensor, When it is determined that there is no warm water, the heating operation by the heater is prohibited, the open / close control valve is opened and the inside of the warm water tank is purged with air, and water is poured into the warm water tank from the water source container along with the air purge. Above, the water server characterized by permitting the heating operation by the said heater. The water server according to claim 1,
The water detection sensor is a water server that is a self-heating type thermistor and is configured to detect whether or not water is present due to a temperature change during self-heating in addition to temperature detection. A warm water tank that is configured by a sealed container and receives water supply from the water source container installed at the upper level by a head difference, a heater that heats the water in the warm water tank to generate warm water, and switches the warm water from the warm water tank to open and close An open / close control valve that can take water and supply it to the outside, a temperature / water detection sensor that detects whether there is water due to a temperature change during self-heating in addition to the water temperature detection in the hot water tank, and this temperature / water Control means for controlling the operation based on the output from the detection sensor,
The control means, upon receiving the ON output from the operation switch for generating hot water, whether hot water into the hot water tank on the basis of a comparison between the detected temperature and determine the temperature from the temperature and water detection sensor is present When the determination is other than the determination that there is hot water, the heating operation by the heater is prohibited, and the temperature / water detection sensor further determines whether there is water in the hot water tank. When it is determined that there is no water, the opening / closing control valve is opened and closed while the heating operation by the heater is prohibited, and the hot water tank is purged with air, and water is poured from the water source container into the warm water tank along with the air purge. A water server configured to allow heating operation by the heater. A warm water tank that is configured by a sealed container and receives water supply from the water source container installed at the upper level by a head difference, a heater that heats the water in the warm water tank to generate warm water, and switches the warm water from the warm water tank to open and close An open / close control valve that can take water and supply it to the outside, a temperature / water detection sensor that detects whether there is water due to a temperature change during self-heating in addition to the water temperature detection in the hot water tank, and this temperature / water Control means for controlling the operation based on the output from the detection sensor,
The control means, when the output condition of the request command is a heater heating demand of the heating operation by the heater is established, the temperature water in the hot water tank on the basis of a comparison between the detected temperature and determine the temperature from the temperature and water detection sensor a judgment of whether or not there, be prohibited heating operation by the heater, further the temperature and water detection as above Kihi over data heating request is output when the determination of non-determination of the hot water there The sensor determines whether or not there is water in the hot water tank. If it is determined that there is no water, the heating control by the heater is prohibited and the open / close control valve is opened and purged in the hot water tank. A water server configured to permit heating operation by the heater after water is poured from the water source container into the hot water tank in association with air purge. The water server according to claim 3 or claim 4,
The above temperature / water detection sensor is a self-heating type thermistor. In addition to temperature detection by energizing the normal power supply, whether water is present due to temperature change at the time of self-heating by self-heating by switching to the power supply for water detection A water server configured to detect whether or not.

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