JP2005308353A - Method of detecting failure of water supply flow rate sensor of hot water storage type hot water supply system, and hot water storage type hot water supply system using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hot water storage type hot water supply system capable of notifying a user of the failure with a simple constitution when a water supply flow rate sensor is failed. <P>SOLUTION: This system comprises a hot water storage tank, a hot water supply pipe for supplying the hot water of high temperature to the hot water storage tank, a water supply pipe for supplying the water of low temperature to the hot water storage tank, a water supply flow rate sensor mounted on the water supply pipe for measuring a flow rate of the water of low temperature supplied to the hot water storage tank, a water level sensor for measuring a water level of the water of low temperature by a plurality of temperature sensors mounted on the hot water storage tank, a display part for displaying an operation state of the water supply flow rate sensor, and a control part electrically connected with the hot water flow rate sensor and the water level sensor to recognize the measurement data and to display a result on the display part. The water supply flow rate measured by the water supply flow rate sensor and a water supply flow rate estimated on the basis of a measured value of the water level sensor are compared by the control part, and the failure of the water supply flow rate sensor is displayed on the display part when it is judged that the difference between both water supply flow rates is more than a specific value. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a failure detection method for a water supply flow rate sensor for measuring the flow rate of low temperature water supplied to a hot water storage tank storing high temperature hot water or low temperature water, and a hot water storage type hot water supply system using the same.

  Conventionally, as disclosed in Japanese Patent Application Laid-Open No. 2003-294251, a hot water storage hot water supply system that stores hot water in a hot water storage tank and supplies it to a user has been used. In such a hot water storage tank, low temperature water is supplied from the bottom and high temperature hot water is supplied from the top, and the hot water storage tank is filled with high temperature hot water or low temperature water.

Further, as disclosed in Japanese Patent Laid-Open No. 9-257304, a water supply flow rate sensor (counter) is provided in a water supply pipe for supplying low temperature water, and the flow rate of low temperature water supplied to a hot water storage tank is controlled. Measuring. As a structure of such a water supply flow rate sensor, there is one that has an impeller inside, the impeller rotates according to the flow rate of water, and the flow rate is measured by this rotational speed. However, since this structure has a mechanical moving part, there is a high possibility of failure as compared with a temperature sensor consisting only of electronic components. Moreover, when an operating part such as this impeller fails, it is not easy to automatically detect this failure. As a method for detecting a failure of a water supply flow rate sensor, Japanese Patent Application Laid-Open No. 9-257304 discloses a method of providing a plurality of water supply flow rate sensors. However, this method requires a plurality of water supply flow rate sensors, which complicates the structure and increases the cost.
JP 2003-294251 A JP-A-9-257304

  The present invention has been made in view of the above points, and an object of the present invention is to provide a hot water storage type hot water supply in which a user can know the failure with a simple configuration when the water supply flow rate sensor fails. To provide a system.

  In order to solve the above problems, a hot water storage hot water system according to the present invention includes a hot water storage tank in which high temperature hot water or low temperature water is stored, a hot water supply pipe for supplying high temperature hot water to the hot water storage tank, and low temperature water to the hot water storage tank. A water supply pipe, a water supply flow sensor that measures the flow rate of low-temperature water that is attached to the water supply pipe and supplies the hot water storage tank, a water level sensor that measures the water level of low-temperature water using multiple temperature sensors attached to the hot water storage tank, and a water supply flow A display unit that displays an operation state of the sensor, and a control unit that is electrically connected to the water supply flow rate sensor and the water level sensor and can recognize the measurement data and display the result on the display unit. The control unit compares the feedwater flow rate measured by the feedwater flow rate sensor with the feedwater flow rate estimated from the measured value of the water level sensor. If it is determined that there is is characterized in that it is for displaying on the display unit that feedwater flow sensor is faulty.

  In the present invention, the control unit compares the feed water flow rate measured by the feed water flow rate sensor with the feed water flow rate estimated from the measurement value of the water level sensor, and there is a difference of a certain value or more between the two feed water flow rates. When it is determined that there is a failure, the display unit displays that the water supply flow rate sensor is out of order, so that the user can automatically know the failure of the water supply flow rate sensor.

  The structure of the hot water storage type hot water supply system of this embodiment will be described with reference to FIG. As shown in FIG. 1, this hot water storage type hot water supply system has a sealed structure in which a substantially hemispherical top and bottom are provided above and below a cylindrical side surface, depending on the needs of the user. Hot water is supplied. A water supply pipe 2 for supplying low temperature water to the hot water storage tank 1 and a heater water supply pipe 3 for supplying low temperature water from the hot water storage tank 1 to the heating device 9 are attached to the bottom of the hot water storage tank 1. Yes. A hot water supply pipe 4 for supplying high temperature hot water to the hot water storage tank 1 and a hot water supply pipe 5 for supplying high temperature hot water to the user from the hot water storage tank 1 through the mixing plug 20 are provided at the top of the hot water storage tank 1. And are attached. The water supply pipe 2 is provided with a water supply flow rate sensor 6 for measuring the flow rate of the low temperature water supplied to the hot water storage tank 1 and a water supply temperature sensor 7 for measuring the temperature of the low temperature water. The feed water flow rate measured by the feed water flow rate sensor 6 and the temperature of the low temperature water measured by the feed water temperature sensor 7 are transmitted to the control unit 16 as electrical signals, and the result is displayed on the display unit 17. Here, the water supply flow rate sensor 6 includes a sensor that rotates an impeller attached to the inside of the water supply pipe 2 according to the flow rate of low-temperature water and measures the flow rate from this rotational speed. The water supply pipe 2 is connected to a water pipe 21 so that low temperature water is supplied from an external water supply.

  A heating device 9 is attached to the tip of the heater water supply pipe 3 to heat the low-temperature water supplied from the hot water storage tank 1. Here, as the heating device 9, a heat pump is often used, but is not limited thereto, and may be a boiler or the like. The hot water heated to a high temperature by the heating device 9 is supplied to the hot water supply tank 1 from the top through the heater hot water supply pipe 4. As a result, low temperature water 11 is stored below the hot water supply tank 1, and high temperature hot water 12 is stored above the hot water tank 1, and the interior is full. Here, the hot water 12 and the low temperature water 11 do not mix with each other, and form a hot water boundary surface 13. A plurality of temperature sensors 14 are attached to the inner surface of the hot water tank 1. A specific example of the temperature sensor 14 is a thermistor element, but is not limited thereto. As described above, since the hot water 12 and the low temperature water 11 do not cross each other, the position of the hot water boundary surface 13 is estimated by knowing the temperature distribution inside the hot water storage tank 1 from these temperature sensors 14. be able to. That is, the temperature sensor 14 functions as a water level sensor 15 that measures the water level of low-temperature water as a whole. Information on the position of the hot water boundary surface 13 estimated by the water level sensor 15 is transmitted to the control unit 16 as an electrical signal. The water level sensor 15 provided with the plurality of temperature sensors 14 is originally for estimating the position of the hot / cold water interface 13 and issuing a command signal for operating / stopping the heating device 9 and the circulation pump 10. Yes, it was also attached to the hot water storage tank of the conventional hot water storage type hot water supply system.

  On the other hand, the hot water 12 is supplied from the hot water storage tank 1 through the hot water supply pipe 5 attached to the top of the hot water storage tank 1. The hot water supply pipe 5 is provided with a hot water supply temperature sensor 8 to measure the temperature of the hot water and transmit this information to the control unit 16 as an electrical signal. Although this hot water may be used directly, in this embodiment, the hot water is supplied from the low temperature water supplied from the second water supply pipe 22 connected to the water pipe 21 and the mixing valve 18. Mixed hot water mixed to a predetermined temperature is supplied from the mixing plug 20 through the hot water mixing pipe 19.

  Below, operation | movement of the hot water storage type hot-water supply system of this embodiment is demonstrated. As described above, the hot water storage tank 1 is in a state where the low temperature water 11 is stored on the lower side of the hot water supply tank 1 and the high temperature hot water 12 is stored on the upper side, and the interior is full. Here, when the user consumes the hot water 12 through the hot water supply pipe 5 and the mixing plug 20, the same amount of low temperature water as the high temperature hot water is supplied to the hot water storage tank 1 through the water supply pipe 2. As a result, the hot water storage tank 1 is maintained in a full tank state by the high temperature hot water 12 and the low temperature water 11, while the hot water boundary surface 13 moves upward. At this time, a change in the hot water boundary surface 13 can be estimated from the temperature distribution inside the hot water storage tank 1 measured by the temperature sensor 14. This result is transmitted from the water level sensor 15 to the control unit 16 as an electrical signal. The flow rate of the low-temperature water supplied from the water supply pipe 2 is measured by the water supply flow rate sensor 6, and the result is transmitted to the control unit 16 as an electrical signal.

  Here, when the amount of the hot water 12 stored in the hot water storage tank 1 decreases and the hot water boundary surface 13 rises to a predetermined value or less, this information is sent to the control unit 16 by an electrical signal from the water level sensor 15. Since it is transmitted, a command for operating the heating device 9 and the circulation pump 10 is issued as an electrical signal. Thereby, low temperature water 11 is supplied to the heating device 9 from the bottom of the hot water storage tank 1 through the heater water supply pipe 3. Here, the hot water is heated to become hot water, and hot water 12 is supplied from the top to the hot water storage tank 1 through the heater hot water supply pipe 4. At this time, the amount of the low temperature water 11 coming out of the hot water storage tank 1 and the amount of the high temperature hot water 12 entering the hot water storage tank 1 are the same. The surface 13 moves downward. This information is detected by the water level sensor 15 via the temperature sensor 14 and transmitted to the control unit 16 as an electrical signal. And when the hot-water boundary surface 13 becomes below a predetermined value, the control part 16 will emit the electric signal which stops the heating apparatus 9 and the circulation pump 10. FIG. By these series of operations, the hot water storage tank 1 is maintained in a full tank state by the low temperature water 11 or the high temperature hot water 12 and a certain level or more of the high temperature hot water 12 is stored. Therefore, the user can consume the desired high temperature hot water constantly.

  Here, since the amount of hot water consumed by the user from the hot water storage tank 1 and the amount of low temperature water supplied to the hot water storage tank 1 through the water supply pipe 2 are equal, the water supply flow rate measured by the water supply flow rate sensor 6 is integrated. The low-temperature water amount r1 thus shown indicates the amount of high-temperature hot water supplied to the user. Further, the temperature t1 of the low temperature water and the temperature t2 of the high temperature hot water can be known by the water supply temperature sensor 7 and the hot water temperature sensor 8, respectively. Therefore, the total amount of heat Q (kcal) consumed by the user can be known by the following equation.

Q = (t2−t1) × r1
The total heat quantity Q is calculated by the control unit 16 and displayed on the display unit 17. Knowing this total heat quantity Q makes it possible to manage the energy of this hot water storage hot water supply system. Furthermore, by comparing with the energy used by the heating device 9, it is possible to know the energy efficiency of this hot water storage hot water supply system, and to take measures to further promote energy saving.

  Here, the control unit 16 compares the feed water flow rate transmitted from the feed water flow rate sensor 6 and the feed water flow rate estimated from the temporal change amount of the hot / cold water interface 13 estimated by the water level sensor 15, and both are constant. If there is a difference as described above, it is considered that either the feed water flow rate sensor 6 or the water level sensor 15 is abnormal. The temperature sensor 14 that constitutes the water level sensor 15 has no operating part, so that the possibility of failure is low. On the other hand, the water supply flow rate sensor 6 has an operating part and is likely to fail. Therefore, in this embodiment, in such a case, it is determined that the water supply flow rate sensor 6 is out of order, and that effect is displayed on the display unit 17.

  Here, when only the water supply flow rate sensor 6 fails for some reason, it becomes impossible to know the total amount of heat Q consumed by the user, and it becomes inconvenient that energy management of this hot water storage type hot water supply system cannot be performed. . However, even if only the water supply flow rate sensor 6 breaks down, there is no problem in supplying hot water to the user. Therefore, as in the case of commercial hot water storage hot water supply systems, if the supply of high-temperature hot water to the user stops, the business will be hindered and the inconvenience will be caused, but the user is limited. It can be said that the effect of being able to continue using the hot water storage type hot water supply system in a state where the failure of the water supply flow rate sensor 6 is displayed is great. Thus, when there is an indication on the display unit 17 that the water supply flow rate sensor 6 is out of order, the user instructs the repair company or the like to repair and continues to use this hot water storage type hot water supply system. Can do.

  In addition, when it is not determined that such a failure is detected (the difference between the flow rates of the hot water flow rate measured by the feed water flow rate sensor and the hot water flow rate estimated from the measured value of the water level sensor is less than a certain value. If it is determined that the water supply flow rate sensor 6 is normal, the fact that it is displayed on the display unit 17 indicates that the user has confirmed that the water supply flow rate sensor 6 has not failed. it can.

  The failure detection method of the feed water flow sensor of the present embodiment is such that the control unit compares the feed water flow measured by the feed water flow sensor with the hot water flow measured from the measured value of the water level sensor, and a constant value between the two flows. If it is determined that there is a difference as described above, it is detected that the water supply flow rate sensor is out of order on the display unit. Therefore, the failure of the water supply flow rate sensor is known without adding a complicated configuration such as providing another sensor. You can instruct repairs as soon as possible. As a result, the total amount of heat used in the hot water storage hot water supply system provided with the water supply flow rate sensor is not erroneously known, and energy management and the like can be reliably performed.

  Moreover, the hot water storage type hot water supply system using the failure detection method for the water supply flow rate sensor of the present embodiment allows the user to know the failure of the water supply flow rate sensor by displaying the display unit. Moreover, even if this water supply flow sensor is out of order and instructing repair of the failure, the user can consume high-temperature hot water. This is particularly effective when the user is limited and the degree of trouble caused by stopping the supply of high-temperature hot water is large, as in a hot water storage hot water supply system for business use.

  Furthermore, when the controller compares the hot water flow rate estimated from the measured value of the feed water flow rate sensor with the measured value of the water level sensor, it is determined that there is no difference between the two flow rates beyond a certain value. Since the display unit displays that the water supply flow rate sensor is normal, the user can use the hot water storage type hot water supply system with peace of mind knowing that the water supply flow rate sensor has not failed.

It is a lineblock diagram of the hot water storage type hot-water supply system of this embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Hot water storage tank 2 Water supply pipe 3 Heater water supply pipe 4 Heater hot water supply pipe 5 Hot water supply pipe 6 Water supply flow rate sensor 7 Water supply temperature sensor 8 Hot water supply temperature sensor 9 Heating device 10 Circulation pump 11 Low temperature water 11 High temperature hot water 13 Hot water interface 14 Temperature sensor 15 Water level sensor 16 Control unit 17 Display unit

Claims (3)

A hot water storage tank in which high temperature hot water or low temperature water is stored, a hot water supply pipe for supplying high temperature hot water to the hot water storage tank, a water supply pipe for supplying low temperature water to the hot water storage tank, and the hot water storage tank attached to the water supply pipe A water supply flow sensor for measuring the flow rate of the low-temperature water supplied to the water, a water level sensor for measuring the water level of the low-temperature water using a plurality of temperature sensors attached to the hot water storage tank, and the water supply flow rate sensor and the water level sensor electrically A control unit connected to recognize the measurement data,
A failure detection method for a water supply flow rate sensor that detects a failure of the water supply flow rate sensor by comparing the water supply flow rate measured by the water supply flow rate sensor with a water supply flow rate estimated from a measurement value of the water level sensor by the control unit. . A hot water storage tank in which high temperature hot water or low temperature water is stored, a hot water supply pipe for supplying high temperature hot water to the hot water storage tank, a water supply pipe for supplying low temperature water to the hot water storage tank, and the hot water storage tank attached to the water supply pipe A water supply flow sensor that measures the flow rate of low-temperature water supplied to the water, a water level sensor that measures the water level of low-temperature water using a plurality of temperature sensors attached to the hot water storage tank, and a display unit that displays the operating state of the water supply flow sensor And a control unit that is electrically connected to the water supply flow rate sensor and the water level sensor and can recognize the measurement data and display the result on the display unit.
When the control unit compares the feed water flow rate measured by the feed water flow rate sensor with the feed water flow rate estimated from the measured value of the water level sensor, and determines that there is a difference of a certain value or more between the two feed water flow rates In the hot water storage type hot water supply system, the display unit displays that the water supply flow rate sensor is out of order. When the control unit compares the feed water flow rate measured by the feed water flow rate sensor and the feed water flow rate estimated from the measurement value of the water level sensor, and determines that the difference between the two feed water flow rates is below a certain value The hot water storage hot water supply system according to claim 2, wherein the display section displays that the water supply flow rate sensor is normal.

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