JP2006057890A - Hot-water supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hot-water supply device capable of easily detecting a failure of a flow rate detection means. <P>SOLUTION: A control device 200 determines that at least either of both flow rate counters 62 and 72 is in a failure state when a flow rate detected by the flow rate counter 62 is smaller than that of the flow rate counter 72, and displays information of the failure state on a display part 110 of an operation panel 100. Thereby, it is annunciated to a user or the like that at least either of the flow rate counters 62 and 72 is in the failure state and repair can be facilitated. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a hot water storage type hot water supply apparatus that stores high temperature hot water for hot water supply in a hot water storage tank, and more particularly to failure detection of a flow rate detection means in a hot water supply and hot water path.

  Conventionally, for example, a hot water supply apparatus as shown in FIG. 4 is known. This hot water supply apparatus mixes hot water discharged from the hot water storage tank 901 via the outlet pipe 914 and tap water supplied via the water supply pipe 915 branched from the introduction pipe 912 that supplies water to the hot water storage tank 901. After mixing by the valve 916, there are two systems for supplying hot water to the use side terminal (for example, bath and currant) via the mixed hot water supply pipe 917.

  The temperature of hot water flowing through each mixed hot water supply pipe 917 is adjusted by a mixing valve 916 of each system, so that hot water at a desired temperature (for example, 40 ° C. and 35 ° C.) can be supplied to each system.

  Then, flow rate counters 961 and 971 are provided for each of the mixed hot water supply pipes 917 so that the amount of hot water used is grasped and used for hot water determination, hot water learning control, and the like.

  However, in the conventional hot water supply apparatus illustrated in FIG. 4, it is very difficult to detect when the flow rate counters 961 and 971 that are the flow rate detection means break down.

  In recent years, the present inventors have started the development of a hot water supply apparatus that supplies fresh hot water to a use-side terminal in one of the hot water supply systems. Here, the raw hot water refers to hot water of about 90 ° C., for example, in which water is not mixed with the hot water discharged from the hot water storage tank.

  In such a hot water supply apparatus, in order to grasp the hot water supply amount of the hot water supply system, a flow rate detection means having high heat resistance is required, which is not practical because it is very expensive. Therefore, the present inventors provide a flow rate detection means at a position where the total amount of water supplied to the hot water supply device can be detected without providing a flow rate detection means in the hot water supply system. Focusing on the fact that the amount of hot water used in the mixed hot water supply system can be ascertained, we are evaluating the prototype.

  The present inventors have illustrated in FIG. 4 that in such a hot water supply apparatus, the flow rate detection means capable of detecting the total water supply amount is disposed upstream of the flow rate detection means capable of detecting the mixed hot water supply amount. It has been found that it is possible to detect a failure of the flow rate detection means, which is very difficult with such a hot water supply apparatus.

  This invention is made | formed in view of the said point, and it aims at providing the hot-water supply apparatus which can detect the failure of a flow volume detection means easily.

In order to achieve the above object, in the invention described in claim 1,
A hot water storage tank (1) for heating the internal water by heating means (2) to form hot water and storing it in the interior;
A water supply path (12) for supplying water into the hot water storage tank (1);
A hot water supply path (24) for supplying only hot water stored in the hot water storage tank (1);
A hot water supply route (14) for hot water stored in the hot water storage tank (1),
A bypass route (15) branched from the water supply route (12) and bypassing the hot water storage tank (1);
The hot water supply route (14) and the bypass route (15) merge, and the hot water flowing through the hot water route (14) and the water flowing through the bypass route (15) are mixed to supply hot water (17),
A first flow rate detection means (62) that is provided upstream of the branch point of the bypass route (15) of the water supply route (12) and detects the flow rate of water flowing through the water supply route (12);
Second flow rate detection means (72) provided in the mixed hot water supply path (17) for detecting the flow rate of hot water flowing through the mixed hot water supply path (17);
Based on the flow rate detected by the first flow rate detection means (62) and the flow rate detected by the second flow rate detection means (72), at least one of the first flow rate detection means (62) and the second flow rate detection means (72). And a failure detection means (200) for detecting that is in a failure state.

  According to this, the failure detection means (200) includes the flow rate supplied to the hot water storage tank (1) and the mixed hot water supply path (17) detected by the first flow rate detection means (62), and the second flow rate detection means (72). It is possible to easily detect that at least one of the first flow rate detection means (62) and the second flow rate detection means (72) is in a failure state based on the flow rate of the mixed hot water supply path (17) detected by It is.

  Specifically, as in the invention described in claim 2, the failure detection means (200) is configured such that the flow rate detected by the first flow rate detection means (62) is greater than the flow rate detected by the second flow rate detection means (72). When it is small, it can be determined that at least one of the first flow rate detection means (62) and the second flow rate detection means (72) is in a failure state.

Further, as in the invention according to claim 3,
It has a calorific value detection means (33-37) for detecting the calorific value in the hot water storage tank (1),
Based on the flow rate detected by the second flow rate detection means (72) and the change in the amount of heat in the hot water storage tank (1) detected by the heat quantity detection means (33-37), the failure detection means (200) 12) and the first flow rate detecting means (62) and the second flow rate detecting means (72) from the degree of deviation between the estimated water supply amount and the flow rate detected by the first flow rate detecting means (62). ) Can be determined to be in a failure state.

In the invention according to claim 4,
Informing means (110) for informing the failure state,
The failure detection means (200) activates the notification means (110) when it is determined that at least one of the first flow rate detection means (62) and the second flow rate detection means (72) is in a failure state. It is characterized by.

  According to this, the notification means (110) notifies the user or the like that at least one of the first flow rate detection means (62) and the second flow rate detection means (72) is in a failure state, and prompts repair. it can.

  Further, the invention according to claim 5 is characterized in that the notification means (110) is a display means (110) for displaying a failure state.

  According to this, it is possible to tell that at least one of the first flow rate detection means (62) and the second flow rate detection means (72) is in a failure state by the display of the display means (110).

  In addition, the code | symbol in the parenthesis attached | subjected to each said means is an example which shows a corresponding relationship with the specific means as described in embodiment mentioned later.

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

(First embodiment)
Drawing 1 is a mimetic diagram showing a schematic structure of a hot water storage type hot-water supply device of a 1st embodiment.

  Reference numeral 1 denotes a metal (for example, stainless steel) hot water storage tank having excellent corrosion resistance, and a heat insulating material (not shown) is disposed on the outer peripheral portion, so that hot water for hot water supply can be kept warm for a long time. ing. The hot water storage tank 1 has a vertically long shape, and an introduction port 11 is provided on the bottom surface. An introduction pipe (corresponding to a water supply path) 12 for introducing tap water into the hot water storage tank 1 is connected to the introduction port 11. .

  The introduction pipe 12 is provided with a water supply thermistor 61 as temperature detection means and a flow rate counter 62 as first flow rate detection means. The water supply thermistor 61 is temperature information in the introduction pipe 12, and the flow rate counter 62 is in the introduction pipe 12. The flow rate information is output to the control device 200 described later.

  A pressure reducing valve 63 is provided upstream of the position where the water supply thermistor 61 and the flow rate counter 62 are provided in the introduction pipe 12, so that tap water is gently introduced into the hot water storage tank 1.

  Further, the downstream side of the position where the water supply thermistor 61 and the flow rate counter 62 of the introduction pipe 12 are provided and the mixing valve 16 described later are connected by a water supply pipe (corresponding to a bypass route) 15.

  On the other hand, a lead-out port 13 is provided at the top of the hot water storage tank 1, and a lead-out pipe (corresponding to a hot water discharge path) 14 for leading out hot water in the hot water storage tank 1 is connected to the lead-out port 13. Reference numeral 16 denotes a mixing valve, which is arranged at the junction of the outlet pipe 14 and the water supply pipe 15. The mixing valve 16 can adjust the mixing ratio between the hot water from the outlet pipe 14 and the tap water from the water supply pipe 15 by adjusting the opening area ratio.

  The mixing valve 16 is an electric valve that drives a valve body by a drive source such as a servo motor, and is actuated by a control signal from a control device 200 to be described later, and outputs an operating state to the control device 200. Yes.

  On the outlet side of the mixing valve 16, a pipe 17, which is a mixed hot water supply passage to a currant or the like, is connected. The pipe 17 is provided with a hot water supply thermistor 71 as temperature detection means and a flow rate counter 72 as second flow rate detection means. The hot water supply thermistor 71 is temperature information in the pipe 17, and the flow rate counter 72 is flow rate in the pipe 17. The information is output to the control device 200 described later.

  In addition, when the flow counter 72 detects the flow of water in the pipe 17, it means that hot water is about to be used in the currant or the like of the mixed hot water use side terminal. At this time, the control device 200 roughly adjusts the opening area ratio of the mixing valve 16 from the temperature information from the feed water thermistor 61 described later and the temperature information from the hot water thermistor 32 described later according to the set temperature, and then the hot water supply thermistor. Based on the temperature information from 71, the opening area ratio of the mixing valve 16 is finely controlled so that the hot water supply temperature becomes the set temperature.

  A lead-out port 23 is also provided at the top of the hot water storage tank 1, and a pipe (corresponding to a high-temperature hot water supply path) 24 for leading out hot water in the hot water storage tank 1 is connected to the lead-out port 23. The pipe 24 directly supplies hot water (for example, 90 ° C. hot water) in the hot water storage tank 1 directly to a device (for example, a commercial dishwasher) or a currant provided at a terminal on the downstream side where hot water is used. Hot water supply (without mixing).

  A suction port 18 for sucking water in the hot water storage tank 1 is provided on the lower surface of the hot water storage tank 1, and a discharge port 19 for discharging hot water into the hot water storage tank 1 is provided on the upper surface of the hot water storage tank 1. Yes. The suction port 18 and the discharge port 19 are connected by a circulation circuit 20, and a part of the circulation circuit 20 is disposed in the heat pump unit 2. A heat exchanger (not shown) is provided in a portion of the circulation circuit 20 disposed in the heat pump unit 2, and heats the water in the hot water storage tank 1 sucked from the suction port 18 by heat exchange with the high-temperature refrigerant, The water in the hot water storage tank 1 can be boiled by returning it from the discharge port 19 into the hot water storage tank 1.

  The heat pump unit 2 is a heating unit in the present embodiment. The heat pump unit 2 is operated by a control signal from a control device 200 described later, and outputs an operation state to the control device 200.

  A water thermistor 31 for detecting the water temperature in the lower part of the hot water storage tank 1 is provided on the lower outer wall surface of the hot water storage tank 1 so that temperature information of the water introduced from the introduction port 11 is output to the control device 200 described later. It has become. Further, a hot water thermistor 32 for detecting the water temperature in the upper part of the hot water storage tank 1 is provided on the upper outer wall surface of the hot water storage tank 1, and the temperature information of the hot water led out from the outlets 13 and 23 will be described later. To output.

  When the heat pump unit 2 that is a heating means heats the water in the circulation circuit 20 by a heat exchanger (not shown) provided in the circulation circuit 20, the control device 200 uses the heat pump based on the temperature information from the incoming water thermistor 31. The operation of the unit 2 is controlled.

  In addition, a plurality (five in this example) of water level thermistors 33 to 37 are arranged on the outer wall surface of the hot water storage tank 1 at substantially equal intervals in the vertical direction. The temperature information is output to the control device 200 described later.

  For example, when five water level thermistors 33 to 37 are provided on the outer wall surface of the hot water storage tank 1 having a capacity of 300 L, temperature information of the water level in increments of 50 L is output and the hot water heated above the hot water storage tank 1 is heated. And a boundary surface between the hot water tank 1 and the water before boiling in the hot water storage tank 1 can be detected in increments of 50L.

  Reference numeral 100 denotes an operation panel for setting / displaying control conditions. The operation panel 100 outputs various operation switch signals to a control device 200 to be described later, and displays the display unit 110 as a display unit according to a control signal from the control device 200. To do.

  Reference numeral 200 denotes a control device which is a control means, such as temperature information from each of the thermistors 31 to 37, 61, 71, flow information from the flow counters 62, 72, a signal from an operation switch provided on the operation panel 100, and the like. Is configured to control the heat pump unit 2, the mixing valve 16, the display unit 110 of the operation panel 100, and the like.

  Next, the flow counter failure detection operation of the hot water supply apparatus of the present embodiment will be described based on the above configuration.

  FIG. 2 is a flowchart showing the flow counter failure detection operation of the control device 200. The control device 200 is a failure detection unit in the present embodiment, and the display unit 110 of the operation panel 100 that is a display unit that displays a failure state is a notification unit in the present embodiment.

  When power is supplied, the control device 200 first inputs flow rate information from the flow rate counter 62 and the flow rate counter 72 (step S110). Next, the flow rate detected by the flow rate counter 62 is compared with the flow rate detected by the flow rate counter 72 to determine whether or not the flow rate detected by the flow rate counter 62 is equal to or higher than the flow rate detected by the flow rate counter 72 ( Step S120).

  When both flow counters 62 and 72 are normal (when there is no failure), the flow rate detected by the flow rate counter 62 is never smaller than the flow rate detected by the flow rate counter 72.

  Therefore, when the flow rate detected by the flow rate counter 62 is smaller than the flow rate detected by the flow rate counter 72 (when NO is determined in step S120), at least one of the flow rate counters 62 and 72 is out of order. Therefore, the control device 200 displays on the display unit 110 of the operation panel 100 that the flow counter has failed (for example, an error code display) (step S130).

  If YES is determined in step S120 and if step S130 is executed, the process returns to step S110.

  According to the configuration and operation described above, when the detected flow rate of the flow rate counter 62 is smaller than the detected flow rate of the flow rate counter 72, the control device 200 determines that at least one of the flow rate counters 62 and 72 is in a failure state. The display unit 110 of the operation panel 100 displays a failure state. As a result, it is possible to notify the user or the like that at least one of the flow counters 62 and 72 has a failure, and prompt repair.

  If either of the flow counters 62 and 72 breaks down, it becomes difficult for the control device 200 to check the hot water supply and grasp the hot water supply amount, and the accuracy of the boiling control (so-called learning control) according to the actual use of the hot water supply is remarkably high. descend. In addition, when the flow rate counter 62 fails, it is difficult to confirm the start of hot water supply (hot water) performed via the pipe 24. Therefore, it is performed via the pipe 17 at the moment when the hot water supply starts. It becomes difficult to suppress the temperature change of the mixed hot water.

  Therefore, if the hot water supply apparatus of the present embodiment can inform at least one of the flow rate counters 62 and 72 that there is a failure and prompt the repair, the malfunction of the hot water supply apparatus can be quickly resolved.

  In the failure detection operation of the present embodiment, it is difficult to detect a failure when the flow rate counter 72 enters a failure state in which the flow rate is lower than the actual flow rate or detects a flow rate of 0. However, since the flow counter 72 has a shorter operation time (frequency) than the flow counter 62, the flow counter 62 is more likely to fail, and the failure mode of the flow counter 62 detects a flow rate lower than the actual flow rate. In many cases, the flow rate is zero. Therefore, according to the failure detection operation of the present embodiment, it is possible to detect most of the failures in the flow counter.

(Second Embodiment)
Next, a second embodiment will be described based on FIG. 1 and FIG.

  The second embodiment differs from the first embodiment in the failure detection operation of the flow counter. In addition, about the part similar to 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  A plurality of water level thermistors 33 to 37 on the outer wall surface of the hot water storage tank 1 shown in FIG. 1 are heat quantity detection means in the present embodiment, and the control device 200 is based on temperature information from the water level thermistors 33 to 37. The amount of heat (the amount of hot water) in 1 can be detected.

  Next, the flow counter failure detection operation of the hot water supply apparatus of the present embodiment will be described based on the above configuration.

  FIG. 3 is a flowchart showing the flow counter failure detection operation of the control device 200 in the second embodiment.

  When power is supplied, the control device 200 according to the present embodiment first inputs flow rate information from the flow rate counter 62 and the flow rate counter 72, and inputs temperature information from the water level thermistors 33 to 37 (step S210). Then, based on the flow rate detected by the flow rate counter 72 and the change in the amount of heat in the hot water storage tank 1 calculated from the temperature information from the water level thermistors 33 to 37, the amount of water supplied to the hot water supply device via the introduction pipe 12 is determined. Estimate (step S220).

  The change in the amount of heat (hot water amount) in the hot water storage tank 1 is mainly caused by the hot water supply to the pipe 17 side (mixed hot water supply system) via the outlet pipe 14 and the hot water supply (to the high temperature hot water supply system) via the pipe 24. That is, it can be estimated that the amount of water supply corresponding to the decrease in the amount of hot water was performed in the hot water storage tank 1 via the introduction pipe 12.

  On the other hand, the detected flow rate of the flow rate counter 72 is the sum of the amount of hot water discharged via the outlet pipe 14 and the amount of water supplied via the water supply pipe 15, so that the water supply pipe is referred to by referring to the hot water supply temperature or the opening ratio of the mixing valve. 15 can be estimated.

  Therefore, in step S220, the total water supply amount can be estimated from the estimated water supply amount into the hot water storage tank 1 and the estimated water supply amount via the water supply pipe 15.

  When the water supply amount is estimated in step S220, the degree of divergence between the estimated water supply amount and the detected flow rate of the flow rate counter 62 is determined (step S230).

  If the difference between the estimated water supply amount and the detected flow rate of the flow rate counter 62 is smaller than the predetermined amount in step S230 (if NO is determined in step S230), at least one of the flow rate counters 62 and 72 is out of order. Since this is the case, the control device 200 displays on the display unit 110 of the operation panel 100 that the flow counter has failed (for example, an error code display) (step S130).

  If YES is determined in step S230, and if step S130 is executed, the process returns to step S210.

  According to the above-described configuration and operation, the control device 200 controls the introduction pipe 12 based on the flow rate detected by the flow rate counter 72 and the heat amount change in the hot water storage tank 1 calculated from the temperature information of the water level thermistors 33 to 37. If the difference between the estimated water supply amount and the detected flow rate of the flow rate counter 62 is smaller than a predetermined amount, at least one of the flow rate counters 62 and 72 is in a failure state. A determination is made and a message indicating a failure state is displayed on the display unit 110 of the operation panel 100. As a result, similarly to the first embodiment, it is possible to notify the user or the like that at least one of the flow counters 62 and 72 has a failure and prompt repair.

  In addition, in step S230 of the detection operation flow, the predetermined value serving as a determination criterion can be changed as appropriate according to various characteristics of the hot water supply device, and the failure detection accuracy can be improved.

(Other embodiments)
In each of the above embodiments, each flow rate detection means is the flow rate counter 62 or 72, but is not limited to this as long as the flow rate can be detected.

  Moreover, in each said embodiment, although the water in the hot water storage tank 1 was boiled using the heat pump unit 2 as a heating means, if it can heat the water in the hot water storage tank 1, it will not restrict to this. For example, an electric heater may be provided in the hot water storage tank 1 to control the heat generation to boil water in the hot water storage tank 1.

  Moreover, in each said embodiment, although the alerting | reporting means of the failure state was the display part 110 of the operation panel 100, it is not limited to this. For example, it may be a display means provided other than the operation panel, or a means for generating a notification sound.

  Moreover, in each said embodiment, real numbers, such as 50L, 300L, and five, are illustrations, Comprising: It can set suitably according to the various characteristics etc. of a hot water storage type hot-water supply apparatus.

It is a schematic diagram which shows schematic structure of the hot water supply apparatus in 1st, 2nd embodiment to which this invention is applied. It is a flowchart which shows the flow counter failure detection operation | movement of the control apparatus 200 in 1st Embodiment. It is a flowchart which shows the flow counter failure detection operation | movement of the control apparatus 200 in 2nd Embodiment. It is a schematic diagram which shows schematic structure of the hot water supply apparatus of a prior art example.

Explanation of symbols

1 Hot water storage tank 2 Heat pump unit (heating means)
12 Introduction pipe (water supply route)
14 Outlet pipe (outflow route)
15 Water supply piping (bypass route)
17 Piping (mixed hot water supply route)
24 Piping (High temperature hot water supply route)
33, 34, 35, 36, 37 Water level thermistor (heat quantity detection means)
62 Flow counter (first flow detection means)
72 Flow counter (second flow detection means)
110 Display section (notification means, display means)
200 Control device (control means, failure detection means)

Claims (5)

A hot water storage tank (1) for heating the internal water by heating means (2) to form hot water and storing it in the interior;
A water supply path (12) for supplying water into the hot water storage tank (1);
A high temperature hot water supply path (24) for supplying only hot water stored in the hot water storage tank (1);
A hot water supply route (14) for hot water stored in the hot water storage tank (1);
A bypass path (15) branched from the water supply path (12) and bypassing the hot water storage tank (1);
The hot water supply path (14) and the bypass path (15) merge, and the hot water flowing through the hot water path (14) and the water flowing through the bypass path (15) are mixed to supply hot water ( 17)
A first flow rate detecting means (62) provided upstream of the bypass route (15) branch point of the water supply route (12) and detecting the flow rate of water flowing through the water supply route (12);
Second flow rate detection means (72) provided in the mixed hot water supply path (17) for detecting the flow rate of hot water flowing through the mixed hot water supply path (17);
Based on the flow rate detected by the first flow rate detection means (62) and the flow rate detected by the second flow rate detection means (72), the first flow rate detection means (62) and the second flow rate detection means (72). ), And a failure detection means (200) for detecting that at least one of them is in a failure state.   When the flow rate detected by the first flow rate detection unit (62) is smaller than the flow rate detected by the second flow rate detection unit (72), the failure detection unit (200) is configured to detect the first flow rate detection unit (62). The hot water supply device according to claim 1, wherein at least one of the second flow rate detection means (72) is determined to be in a failure state. A calorific value detecting means (33-37) for detecting the calorific value in the hot water storage tank (1);
The failure detection means (200) is based on the flow rate detected by the second flow rate detection means (72) and the change in the amount of heat in the hot water storage tank (1) detected by the heat quantity detection means (33-37). Then, the amount of water supplied through the water supply path (12) is estimated, and the first flow rate detection means (62) is calculated from the degree of deviation between the estimated water supply amount and the flow rate detected by the first flow rate detection means (62). The hot water supply device according to claim 1, wherein at least one of the second flow rate detection means (72) is determined to be in a failure state. Informing means (110) for informing the failure state,
When the failure detection means (200) determines that at least one of the first flow rate detection means (62) and the second flow rate detection means (72) is in a failure state, the notification means (110) The hot water supply device according to any one of claims 1 to 3, wherein the hot water supply device is operated.   The hot water supply apparatus according to claim 4, wherein the notification means (110) is a display means (110) for displaying that the failure state is present.

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