JP2006349202A - Hybrid hot water supply system - Google Patents
Hybrid hot water supply system Download PDFInfo
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- JP2006349202A JP2006349202A JP2005172065A JP2005172065A JP2006349202A JP 2006349202 A JP2006349202 A JP 2006349202A JP 2005172065 A JP2005172065 A JP 2005172065A JP 2005172065 A JP2005172065 A JP 2005172065A JP 2006349202 A JP2006349202 A JP 2006349202A
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- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 title claims abstract description 611
- 238000010438 heat treatment Methods 0.000 claims description 13
- 239000003507 refrigerant Substances 0.000 claims description 7
- CURLTUGMZLYLDI-UHFFFAOYSA-N Carbon dioxide Chemical compound O=C=O CURLTUGMZLYLDI-UHFFFAOYSA-N 0.000 claims description 6
- 230000005855 radiation Effects 0.000 claims description 5
- 229910002092 carbon dioxide Inorganic materials 0.000 claims description 3
- 239000001569 carbon dioxide Substances 0.000 claims description 3
- 238000010304 firing Methods 0.000 abstract 2
- 239000008236 heating water Substances 0.000 abstract 1
- 238000010586 diagram Methods 0.000 description 5
- 230000007423 decrease Effects 0.000 description 4
- 239000008400 supply water Substances 0.000 description 4
- 238000011144 upstream manufacturing Methods 0.000 description 4
- 239000002826 coolant Substances 0.000 description 2
- 238000001514 detection method Methods 0.000 description 2
- 230000005611 electricity Effects 0.000 description 2
- 230000007257 malfunction Effects 0.000 description 2
- 238000010792 warming Methods 0.000 description 2
- KYKAJFCTULSVSH-UHFFFAOYSA-N chloro(fluoro)methane Chemical compound F[C]Cl KYKAJFCTULSVSH-UHFFFAOYSA-N 0.000 description 1
- 230000010485 coping Effects 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 238000005485 electric heating Methods 0.000 description 1
- NBVXSUQYWXRMNV-UHFFFAOYSA-N fluoromethane Chemical compound FC NBVXSUQYWXRMNV-UHFFFAOYSA-N 0.000 description 1
- 230000017525 heat dissipation Effects 0.000 description 1
- 230000006698 induction Effects 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- 238000010992 reflux Methods 0.000 description 1
- 230000001629 suppression Effects 0.000 description 1
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- Heat-Pump Type And Storage Water Heaters (AREA)
Abstract
Description
本発明は、ヒートポンプ回路の凝縮器からの放熱と熱交換して加熱された温水を貯湯タンクに貯湯して貯湯タンクから給湯負荷に対して給湯可能に構成されたヒートポンプ式の給湯システムに関する。 The present invention relates to a heat pump hot water supply system configured to store hot water heated by heat exchange with heat radiation from a condenser of a heat pump circuit in a hot water storage tank so that hot water can be supplied from the hot water storage tank to a hot water supply load.
ヒートポンプ式の給湯システムは、夜間の安価な電力を使用して、夜間の給湯使用量の少ない、低給湯負荷状態となる時間帯に、貯湯タンクに温水を貯めて、翌日の昼間の給湯負荷、例えば風呂やシャワー等の給湯に対して使用するシステムである。当該ヒートポンプ式の給湯システムの概略の構成は、図3に模式的に示すように、ヒートポンプ回路の凝縮器からの放熱と熱交換して水を加熱して給湯するヒートポンプ給湯手段2と、加熱された温水を貯湯する貯湯タンク3を備えた構成となっている。但し、ヒートポンプ給湯手段2の加熱能力は、夜間の低給湯負荷状態を想定して決定されているため、専ら貯湯目的に所定の温度に加熱するだけでよく、短時間での加熱能力は非常に低くなっており、高給湯負荷時に貯湯タンクの温水を消費した場合に温水の給湯能力が不足する場合が生じる。また、ヒートポンプ給湯手段2の加熱能力は、外気温度や水温の影響も受けるため、給湯システムとしては安全率を高く設定しておく必要があり、能力的に過剰なシステムとなることもある。また、貯湯タンク3の貯湯量も日常の給湯需要に対して湯切れが起きないように実際の需要量より多い貯湯量のものを使用することになり、成績係数が高いとされているヒートポンプ式の給湯システムではあるが、これは機器側、つまり、ヒートポンプ給湯手段2の性能であり、貯湯タンク3の残湯や放熱等を考慮した実際に給湯として使用するときの実効的な成績係数は低くなってしまう。 The heat pump type hot water supply system uses cheap electricity at night, stores hot water in the hot water storage tank during the time when the amount of hot water use at night is low, and the hot water supply load is low. For example, it is a system used for hot water supply such as a bath or shower. As schematically shown in FIG. 3, the heat pump hot water supply system has a schematic configuration, and heat pump hot water supply means 2 for heating and supplying water by heat exchange with heat radiation from the condenser of the heat pump circuit and being heated. The hot water storage tank 3 for storing hot water is provided. However, since the heating capacity of the heat pump hot water supply means 2 is determined assuming a low hot water supply load state at night, it is only necessary to heat to a predetermined temperature for the purpose of storing hot water, and the heating capacity in a short time is very high. When the hot water in the hot water storage tank is consumed at the time of a high hot water supply load, the hot water supply capacity may be insufficient. Moreover, since the heating capability of the heat pump hot water supply means 2 is also affected by the outside air temperature and the water temperature, it is necessary to set a high safety factor for the hot water supply system, which may result in an excessively efficient system. In addition, the hot water storage tank 3 uses a hot water storage amount that is larger than the actual demand so that the hot water does not run out of daily hot water supply demand. However, this is the performance of the equipment side, that is, the performance of the heat pump hot water supply means 2, and the effective coefficient of performance when actually used as hot water in consideration of the remaining hot water of the hot water storage tank 3 and heat dissipation is low. turn into.
尚、ヒートポンプ回路の冷媒としてCO2を採用したCO2ヒートポンプの場合は、高効率運転(定格での成績係数が年間平均3.0以上)及び高温出湯(約90℃)が可能であるが、ヒートポンプ回路の熱サイクル及び圧縮機の制約から50℃以上の高温での給湯循環運転が困難である。 In the case of a CO 2 heat pump that employs CO 2 as a refrigerant in the heat pump circuit, high-efficiency operation (average performance coefficient of 3.0 or more per year on average) and high-temperature hot water (about 90 ° C.) are possible. The hot water circulation operation at a high temperature of 50 ° C. or more is difficult due to the heat cycle of the heat pump circuit and the restriction of the compressor.
また、ヒートポンプ給湯手段2の加熱能力不足を補い、ヒートポンプ式の給湯システムに必要な給湯能力を確保するために、貯湯タンクと給湯負荷の間に貯湯タンクを備えた電気温水器を設けた給湯システムがある(下記特許文献1参照)。 Further, in order to make up for the lack of heating capacity of the heat pump hot water supply means 2 and to secure the hot water supply capacity necessary for the heat pump hot water supply system, a hot water supply system provided with an electric water heater provided with a hot water storage tank between the hot water storage tank and the hot water supply load. (See Patent Document 1 below).
例えば、特許文献1に開示されているように、ヒートポンプ式の給湯システムに必要な給湯能力を確保するために電気温水器を追加した場合、昼間の高給湯負荷時に電気温水器を作動させる必要があり、昼間の高い電気料金による運転コストの上昇、及び、電気温水器は1次エネルギから見るとエネルギ効率が悪いため、システム全体としての総合的なエネルギ効率が低下する。 For example, as disclosed in Patent Document 1, when an electric water heater is added in order to ensure the hot water supply capacity necessary for the heat pump hot water supply system, it is necessary to operate the electric water heater during a high hot water supply load in the daytime. There is an increase in operating cost due to high electricity charges in the daytime, and the electric water heater is inferior in energy efficiency when viewed from the primary energy, so that the overall energy efficiency of the entire system decreases.
本発明は上記の問題点に鑑みてなされたものであり、その目的は、ヒートポンプ式の給湯システムに必要な給湯能力を高いエネルギ効率を維持して確保可能な給湯システムを提供する点にある。 The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a hot water supply system that can ensure hot water supply capacity necessary for a heat pump hot water supply system while maintaining high energy efficiency.
上記目的を達成するための本発明に係る給湯システムは、ヒートポンプ回路の凝縮器からの放熱と熱交換して水を加熱して給湯するヒートポンプ給湯手段と貯湯タンクを備え、前記ヒートポンプ給湯手段で加熱された温水を前記貯湯タンクに貯湯して前記貯湯タンクから給湯負荷に対して給湯可能に構成された給湯システムであって、前記貯湯タンクから前記給湯負荷への給湯往路に対して、直接或いは補助貯湯タンクを介して給湯可能なガス焚または油焚きによる補助給湯手段を備えることを第1の特徴とする。 In order to achieve the above object, a hot water supply system according to the present invention comprises a heat pump hot water supply means and a hot water storage tank for heating and supplying hot water by exchanging heat with heat from a condenser of a heat pump circuit, and heating by the heat pump hot water supply means. A hot water supply system configured to store hot water in the hot water storage tank and supply hot water from the hot water storage tank to a hot water supply load, directly or auxiliary to a hot water supply path from the hot water storage tank to the hot water supply load A first feature is to provide auxiliary hot water supply means by gas tank or oiling that can supply hot water via a hot water storage tank.
更に、上記特徴の本発明に係る給湯システムは、1日の内の低給湯負荷状態となる主として夜間を含む第1時間帯に、所定量の温水を前記ヒートポンプ給湯手段で加熱して前記貯湯タンクに貯湯し、1日の内の前記第1時間帯以外の第2時間帯に、前記貯湯タンクの貯湯量が所定の第1貯湯量以上である場合は、前記貯湯タンクからのみ前記給湯負荷へ給湯し、前記第2時間帯に、前記貯湯タンクの貯湯量が前記第1貯湯量を下回ると、前記ヒートポンプ給湯手段による温水加熱を追加し、前記第2時間帯に、前記貯湯タンクの貯湯量が前記第1貯湯量より少ない所定の第2貯湯量を下回ると、前記補助給湯手段による給湯を追加することを第2の特徴とする。 Furthermore, in the hot water supply system according to the present invention having the above characteristics, a predetermined amount of hot water is heated by the heat pump hot water supply means in a first time period mainly including nighttime when a low hot water supply load state is reached within one day. If the amount of hot water stored in the hot water storage tank is greater than or equal to a predetermined first hot water storage amount during a second time zone other than the first time zone within a day, the hot water supply load is applied only from the hot water storage tank. When hot water is supplied and the amount of hot water stored in the hot water storage tank falls below the first hot water storage amount during the second time zone, hot water heating is added by the heat pump hot water supply means, and during the second time zone, the hot water storage amount of the hot water storage tank is increased. Is less than a predetermined second hot water storage amount less than the first hot water storage amount, the second feature is that hot water is added by the auxiliary hot water supply means.
更に、上記第2の特徴の本発明に係る給湯システムは、前記第1時間帯において、前記給湯負荷への給湯を前記補助給湯手段により行うことを第3の特徴とする。 Furthermore, the hot water supply system according to the second aspect of the present invention is characterized in that the hot water supply to the hot water supply load is performed by the auxiliary hot water supply means in the first time zone.
更に、上記何れかの特徴の本発明に係る給湯システムは、前記貯湯タンクが、複数のタンクを直列に配列し、その内の連続する2つのタンクの前段の底部と後段の上部を相互に連通させて構成され、前記貯湯タンクの最後列のタンクの底部が、前記ヒートポンプ給湯手段の入水口に連通し、前記貯湯タンクの最前列のタンクの上部が、前記ヒートポンプ給湯手段の出水口に連通していることを第4の特徴とする。 Furthermore, in the hot water supply system according to the present invention having any one of the above characteristics, the hot water storage tank has a plurality of tanks arranged in series, and the bottom part of the front stage and the upper part of the rear stage of two consecutive tanks communicate with each other. The bottom of the last row of the hot water storage tanks communicates with the water inlet of the heat pump hot water supply means, and the top of the frontmost tank of the hot water storage tank communicates with the water outlet of the heat pump hot water supply means This is the fourth feature.
更に、上記第2または第3の特徴の本発明に係る給湯システムは、前記貯湯タンクが、複数のタンクを直列に配列し、その内の連続する2つのタンクの前段の底部と後段の上部を相互に連通させて構成され、前記貯湯タンクの最後列のタンクの底部が、前記ヒートポンプ給湯手段の入水口に連通し、前記貯湯タンクの最前列のタンクの上部が、前記ヒートポンプ給湯手段の出水口に連通し、前記貯湯タンクの貯湯量と前記第1貯湯量との大小比較が、前記複数のタンクの最前列から所定番目のタンクに設けられた温度センサの検出温度により判定され、前記貯湯タンクの貯湯量と前記第2貯湯量との大小比較が、前記所定番目のタンクより前方のタンクに設けられた温度センサの検出温度により判定されることを第5の特徴とする。 Furthermore, in the hot water supply system according to the second or third feature of the present invention, the hot water storage tank has a plurality of tanks arranged in series, and the bottom of the front stage and the upper part of the rear stage of two consecutive tanks among them are arranged. The bottom tank of the last row of the hot water storage tanks communicates with the water inlet of the heat pump hot water supply means, and the upper part of the frontmost tank of the hot water storage tank is the water outlet of the heat pump hot water supply means. The hot water storage amount of the hot water storage tank and the first hot water storage amount are compared by a temperature detected by a temperature sensor provided in a predetermined tank from the front row of the plurality of tanks, and the hot water storage tank A fifth feature is that the comparison between the amount of stored hot water and the amount of stored second hot water is determined by the temperature detected by a temperature sensor provided in a tank in front of the predetermined tank.
更に、上記何れかの特徴の本発明に係る給湯システムは、前記給湯負荷からの給湯復路が前記補助給湯手段の入水口に連通し、前記給湯負荷の循環路上での放熱分を、前記補助給湯手段からの給湯で補うことを第6の特徴とする。 Furthermore, in the hot water supply system according to the present invention having any one of the above features, a hot water return path from the hot water supply load communicates with a water inlet of the auxiliary hot water supply means, and a heat radiation amount on the circulation path of the hot water supply load is reduced to the auxiliary hot water supply. The sixth feature is that the hot water is supplied from the means.
更に、上記何れかの特徴の本発明に係る給湯システムは、前記ヒートポンプ給湯手段のヒートポンプ回路に使用する冷媒が二酸化炭素であることを第7の特徴とする。 Furthermore, the hot water supply system according to the present invention having any one of the above characteristics is characterized in that the refrigerant used in the heat pump circuit of the heat pump hot water supply means is carbon dioxide.
上記各特徴の給湯システムによれば、給湯負荷への給湯往路に対して、直接或いは補助貯湯タンクを介して給湯可能なガス焚または油焚きによる補助給湯手段を備えることで、高給湯負荷時において、給湯システムの給湯能力が不足する場合であっても、補助給湯手段による給湯が可能となり、湯切れを起こさずに安定した給湯が可能となる。また、補助給湯手段を備えることで、ヒートポンプ給湯手段の能力を、翌日の昼間の通常の標準的な給湯需要の温水を貯湯タンクに夜間の間に貯湯するのに必要な能力に設定すればよく、また、貯湯タンクの容量を極度の残湯が生じないように適正化でき、システム全体でのエネルギ効率を向上できる。つまり、給湯能力の不足をヒートポンプ給湯手段の高出力化と貯湯タンクを大型化、或いは、給湯システムを複数使用等によらずに補助給湯手段により解決するため、ヒートポンプ給湯手段を含むヒートポンプ回路、及び、更に、貯湯タンクを小型化でき、給湯システム全体の小型化、低コスト化が図れる。更に、給湯システムの給湯能力が不足する昼間の時間帯に作動させる補助給湯手段が、電気式加熱手段ではなく、ガス焚または油焚きであるため、1次エネルギから見たエネルギ効率の悪い、また、昼間のエネルギコストの高い電力に頼らずに補助給湯が可能なため、エネルギ効率の向上及び運転コストの低減が可能となる。 According to the hot water supply system of each of the above characteristics, the hot water supply path to the hot water supply load is provided with auxiliary hot water supply means that can supply hot water directly or via an auxiliary hot water storage tank, or by hot water supply, so that it can be used at high hot water supply loads. Even when the hot water supply capacity of the hot water supply system is insufficient, hot water can be supplied by the auxiliary hot water supply means, and stable hot water supply is possible without causing hot water to run out. In addition, by providing auxiliary hot water supply means, the capacity of the heat pump hot water supply means may be set to the capacity required to store hot water of normal standard hot water supply demand in the daytime of the next day in the hot water storage tank during the night. In addition, the capacity of the hot water storage tank can be optimized so that no excessive hot water is generated, and the energy efficiency of the entire system can be improved. That is, in order to solve the shortage of hot water supply capacity by increasing the output of the heat pump hot water supply means and increasing the size of the hot water storage tank, or by using auxiliary hot water supply means without using multiple hot water supply systems, etc., a heat pump circuit including the heat pump hot water supply means, and Furthermore, the hot water storage tank can be reduced in size, and the entire hot water supply system can be reduced in size and cost. Furthermore, since the auxiliary hot water supply means that operates during the daytime hours when the hot water supply capacity of the hot water supply system is insufficient is not an electric heating means but a gas tank or oil fired, it is inferior in energy efficiency in terms of primary energy. Since auxiliary hot water can be supplied without relying on electric power with a high energy cost in the daytime, it is possible to improve energy efficiency and reduce operating costs.
特に、上記第2の特徴の給湯システムによれば、低給湯負荷状態となる主として夜間を含む第1時間帯に、第2時間帯における給湯需要を賄うための温水を貯湯タンクに貯湯するため、成績係数の高いヒートポンプ給湯手段を電力料金の安価な時間帯に高効率、低コストで運転させることができる。また、昼間の第2時間帯に、貯湯タンクの貯湯量に応じて、給湯負荷状態を判断して、成績係数の高いヒートポンプ給湯手段から順番に、補助給湯手段までの給湯の能力の追加を行うため、高給湯負荷時においても湯切れを起こすことなく、高効率の給湯が可能となる。 In particular, according to the hot water supply system of the second feature, hot water for supplying hot water supply in the second time zone is stored in the hot water storage tank in the first time zone mainly including nighttime, which is in a low hot water supply load state, A heat pump hot water supply means having a high coefficient of performance can be operated with high efficiency and low cost in an inexpensive time zone of electric power charges. In addition, during the second daytime, the hot water supply load state is determined according to the amount of hot water stored in the hot water storage tank, and the hot water supply capacity from the heat pump hot water supply means having a high coefficient of performance is added in order to the auxiliary hot water supply means. Therefore, highly efficient hot water supply is possible without causing hot water shortage even during a high hot water supply load.
特に、上記第3の特徴の給湯システムによれば、第1時間帯における給湯負荷への給湯を補助給湯手段により行うことで、第1時間帯において、ヒートポンプ給湯手段を貯湯タンクの貯湯のみに使用できるため、第1時間帯に生じる給湯負荷に関係なく、第2時間帯における給湯負荷だけを考慮してヒートポンプ給湯手段及び貯湯タンクの容量等を適正に設定できる。つまり、第2時間帯の高給湯負荷時に対応するための補助給湯手段を、第1時間帯においても有効に活用できることになる。 In particular, according to the hot water supply system of the third feature, the hot pump hot water supply means is used only for hot water storage in the hot water storage tank in the first time zone by performing hot water supply to the hot water supply load in the first time zone by the auxiliary hot water supply means. Therefore, the capacity of the heat pump hot water supply means and the hot water storage tank can be appropriately set in consideration of only the hot water supply load in the second time zone regardless of the hot water supply load generated in the first time zone. That is, the auxiliary hot water supply means for coping with the high hot water supply load in the second time zone can be effectively utilized even in the first time zone.
特に、上記第4の特徴の給湯システムによれば、1つの大きなタンク内での対流による温度変化によって温度センサが誤動作するのを、複数のタンクに分割して対流を抑制し、各タンクに夫々温度センサを配置することで解消できる。 In particular, according to the hot water supply system of the fourth feature, the malfunction of the temperature sensor due to the temperature change due to convection in one large tank is divided into a plurality of tanks to suppress the convection, and each tank is individually controlled. This can be solved by arranging a temperature sensor.
特に、上記第5の特徴の給湯システムによれば、1つの大きなタンク内での対流による温度変化によって温度センサが誤動作するのを、複数のタンクに分割して対流を抑制し、複数のタンクの内の所定のタンク内の温度を正確に検出でき、当該所定のタンク内の貯湯状態を正確に把握でき、上記第2の特徴の作用効果をより確実に奏することができる。 Particularly, according to the hot water supply system of the fifth feature, the malfunction of the temperature sensor due to the temperature change due to convection in one large tank is divided into a plurality of tanks to suppress convection, and The temperature inside the predetermined tank can be accurately detected, the hot water storage state in the predetermined tank can be accurately grasped, and the operational effect of the second feature can be more reliably exhibited.
特に、上記第6の特徴の給湯システムによれば、ヒートポンプ給湯手段の入水口に給湯負荷からの給湯復路を連通して給湯循環運転を行うのが困難な場合、例えば、給湯復路の温水温度が50℃以上でヒートポンプ給湯手段がCO2ヒートポンプである場合等において、給湯循環運転が可能となる。 In particular, according to the hot water supply system of the sixth feature, when it is difficult to perform a hot water supply circulation operation by connecting the hot water supply return path from the hot water supply load to the water inlet of the heat pump hot water supply means, for example, the hot water temperature of the hot water supply return path is When the heat pump hot water supply means is a CO 2 heat pump at 50 ° C. or higher, the hot water supply circulation operation is possible.
特に、上記第7の特徴の給湯システムによれば、CO2の超臨界状態を利用することで従来のフロン系冷媒を使用したヒートポンプ給湯手段に比べて温水を高温(約90℃)に加熱でき、その分貯湯タンクの貯湯容量を小さくでき、給湯システムを小型化できる。また、フロン系冷媒と比較して地球温暖化係数が大幅に小さい(1700分の1)、自然冷媒である二酸化炭素を使用することで、地球温暖化の抑制に貢献できる。 In particular, according to the hot water supply system of the seventh feature, the hot water can be heated to a high temperature (about 90 ° C.) by using the supercritical state of CO 2 as compared with the conventional heat pump hot water supply means using the chlorofluorocarbon refrigerant. Therefore, the hot water storage capacity of the hot water storage tank can be reduced, and the hot water supply system can be downsized. Moreover, it can contribute to suppression of global warming by using carbon dioxide which is a natural refrigerant | coolant whose global warming coefficient is significantly small compared with a fluorocarbon refrigerant | coolant (1/700).
以下、本発明に係る給湯システム(以下、適宜「本発明システム」と略称する)の実施形態を図面に基づいて説明する。 Hereinafter, an embodiment of a hot water supply system according to the present invention (hereinafter abbreviated as “the present invention system” as appropriate) will be described with reference to the drawings.
〈第1実施形態〉
図1は、本発明システムの第1実施形態における概略のシステム構成図である。尚、図中の破線は、各種制御用の信号線を示す。図1に示すように、本発明システム1は、ヒートポンプ給湯手段2、貯湯タンク3、補助給湯手段であるガス焚給湯機4、及び、本発明システム1の運転を制御する制御手段5を備えて構成される。更に、ヒートポンプ給湯手段2と貯湯タンク3とガス焚給湯機4と給湯負荷40の相互間が複数の管路20〜25で接続されている。具体的には、ヒートポンプ給湯手段2の出水口11と給湯負荷40間が給湯往路である管路20で接続され、ヒートポンプ給湯手段2の入水口12と補給水(上水道等)41間が給水路である管路21で接続され、貯湯タンク3の上部入出水口13が管路20に、貯湯タンク3の下部入出水口14が管路21に、夫々接続されている。給湯往路である管路20上の、貯湯タンク3の上部入出水口13との接続個所より下流側(給湯負荷40側)に、温度調整用の3方弁30が介装され、給水路である管路21が、貯湯タンク3の下部入出水口14との接続個所より上流側(補給水41側)で分岐して、3方弁30に接続している。温度調整用の3方弁30は、3方弁30より下流側の管路20に設けられた温度センサ31の検出温度に基づいて、管路21側からの給水量を調整する。
<First Embodiment>
FIG. 1 is a schematic system configuration diagram in the first embodiment of the system of the present invention. In addition, the broken line in a figure shows the signal line for various controls. As shown in FIG. 1, the system 1 of the present invention includes a heat pump hot water supply means 2, a hot water storage tank 3, a gas water heater 4 that is an auxiliary hot water supply means, and a control means 5 that controls the operation of the system 1 of the present invention. Composed. Further, the heat pump hot water supply means 2, the hot water storage tank 3, the gas-fired water heater 4, and the hot water supply load 40 are connected by a plurality of pipe lines 20 to 25. Specifically, the water outlet 11 of the heat pump hot water supply means 2 and the hot water supply load 40 are connected by a pipe 20 that is a hot water supply forward path, and the water supply path is between the water inlet 12 of the heat pump hot water supply means 2 and makeup water (such as waterworks) 41. The upper inlet / outlet 13 of the hot water storage tank 3 is connected to the pipe 20, and the lower inlet / outlet 14 of the hot water storage tank 3 is connected to the pipe 21, respectively. A three-way valve 30 for temperature adjustment is provided downstream from the connection point with the upper inlet / outlet water inlet 13 of the hot water storage tank 3 on the pipe line 20 which is a hot water supply outward path, and is a water supply path. A pipe 21 branches on the upstream side (supply water 41 side) from the connection point with the lower inlet / outlet water inlet 14 of the hot water storage tank 3 and is connected to the three-way valve 30. The three-way valve 30 for temperature adjustment adjusts the amount of water supplied from the pipe 21 side based on the temperature detected by the temperature sensor 31 provided in the pipe 20 downstream of the three-way valve 30.
更に、ガス焚給湯機4の出水口15が、2つの平行な管路22,23を介して、管路20と、3方弁30より下流側において接続している。尚、平行な管路22,23の一方側の管路22には、循環ポンプ32が介装されており、給湯負荷40が循環負荷の場合に作動する。ガス焚給湯機4の入水口16と給湯負荷40間が給湯復路である管路24で接続され、管路24は、管路21の3方弁30への分岐点より上流側と管路25を介して接続されている。更に、管路20上の貯湯タンク3の上部入出水口13との接続点と3方弁30の中間に第1電磁弁33が介装され、管路25上に第2電磁弁34が介装されている。尚、図示していないが、各管路20〜25には、夫々、開閉弁(2方弁)、逆止弁、減圧弁、定流量弁、安全弁、自動空気抜き弁等の内、適宜必要なものが介装されている。また、ヒートポンプ給湯手段2の入水口12の内側にも、図示しないが、開閉弁や循環ポンプが設けられている。 Furthermore, the water outlet 15 of the gas water heater 4 is connected to the pipe 20 on the downstream side of the three-way valve 30 via two parallel pipes 22 and 23. In addition, the circulation pump 32 is interposed in the pipeline 22 on one side of the parallel pipelines 22 and 23, and it operates when the hot water supply load 40 is a circulation load. The inlet 16 of the gas water heater 4 and the hot water supply load 40 are connected by a pipe 24 which is a hot water return path. The pipe 24 is upstream of the branch point of the pipe 21 to the three-way valve 30 and the pipe 25. Connected through. Further, a first electromagnetic valve 33 is interposed between the connection point of the hot water storage tank 3 on the pipeline 20 with the upper inlet / outlet 13 and the three-way valve 30, and a second electromagnetic valve 34 is interposed on the pipeline 25. Has been. Although not shown in the drawings, each of the pipe lines 20 to 25 is necessary as appropriate among an on-off valve (two-way valve), a check valve, a pressure reducing valve, a constant flow valve, a safety valve, an automatic air vent valve, and the like. Things are intervening. Although not shown, an open / close valve and a circulation pump are also provided inside the water inlet 12 of the heat pump hot water supply means 2.
ヒートポンプ給湯手段2は、ヒートポンプ回路の冷媒としてCO2を採用したCO2ヒートポンプで構成され、入水口12から給水された水をヒートポンプ回路の凝縮器からの放熱と熱交換して加熱して、出水口11から管路20を介して貯湯タンク3または給湯負荷40に対して給湯を行う。ヒートポンプ回路の圧縮機は3相誘導電動機で構成され、商用電力(3相200V)を電源として作動する。本実施形態では、例えば、圧縮機の定格出力が8.4kW、加熱能力が21〜26kW程度のものを想定する。 The heat pump hot water supply means 2 is composed of a CO 2 heat pump adopting CO 2 as a refrigerant of the heat pump circuit, and heats the water supplied from the water inlet 12 by exchanging heat with heat released from the condenser of the heat pump circuit. Hot water is supplied from the water port 11 to the hot water storage tank 3 or the hot water supply load 40 via the pipe line 20. The compressor of the heat pump circuit is composed of a three-phase induction motor and operates using commercial power (three-phase 200V) as a power source. In the present embodiment, for example, it is assumed that the compressor has a rated output of 8.4 kW and a heating capacity of about 21 to 26 kW.
貯湯タンク3は、ヒートポンプ給湯手段2から給湯される温水を貯湯して、管路20を介して給湯負荷40に対して給湯を行う。本実施形態では、貯湯タンク3は、6台のタンク3a〜3fを直列に配列し、その内の連続する2つのタンクの前段の底部と後段の上部を相互に連通させて構成される。各タンク容量として500L(リットル)を想定すると、貯湯タンク3の総容量は3000Lとなる。貯湯タンク3の各タンク3a〜3fには内部の水温を計測するサーミスタ等の温度センサ35a〜35fが各別に設けられている。尚、最後列以外の5つのタンク3a〜3eには、温度センサ35a〜35eが夫々、タンク内の上下方向中間位置に設置され、最後列のタンク3fには、温度センサ35fがタンク内の底部に設けられている。 The hot water storage tank 3 stores hot water supplied from the heat pump hot water supply means 2 and supplies hot water to the hot water supply load 40 via the pipe line 20. In the present embodiment, the hot water storage tank 3 is configured by arranging six tanks 3 a to 3 f in series, and communicating the bottom part of the front stage and the upper part of the rear stage of two consecutive tanks among them. Assuming 500 L (liters) as each tank capacity, the total capacity of the hot water storage tank 3 is 3000 L. The tanks 3a to 3f of the hot water storage tank 3 are provided with temperature sensors 35a to 35f such as thermistors for measuring the internal water temperature. The five tanks 3a to 3e other than the last row are provided with temperature sensors 35a to 35e, respectively, at intermediate positions in the vertical direction in the tank, and the temperature sensor 35f is provided at the bottom of the tank in the last row 3f. Is provided.
ガス焚給湯機4は、ヒートポンプ給湯手段2に対する補助的な給湯手段として機能し、本実施形態では、ガス焚真空式ボイラで構成された給湯機を想定する。ガス焚真空式ボイラは、例えば、缶体内の下部にガスバーナの火炎で熱媒水を加熱する火炉を設け、缶体内の上部の減圧空気中にU字状の伝熱管を設け、缶体内の下部に封入された熱媒水をガスバーナの火炎で加熱し、その上部の減圧空気中の伝熱管を加熱して、伝熱管中を流れる水を加熱する構造のものである。本実施形態では、缶体出力が、例えば100kW程度のものを想定する。 The gas fired water heater 4 functions as an auxiliary hot water supply means for the heat pump hot water supply means 2, and in the present embodiment, a hot water heater constituted by a gas fired vacuum boiler is assumed. For example, a gas-fired vacuum boiler is provided with a furnace that heats the heat transfer water with a flame of a gas burner in the lower part of the can body, a U-shaped heat transfer tube in the decompressed air in the upper part of the can body, The heat transfer water sealed in is heated with a flame of a gas burner, the heat transfer tube in the decompressed air above is heated, and the water flowing in the heat transfer tube is heated. In the present embodiment, it is assumed that the can output is, for example, about 100 kW.
制御手段5は、1日の内の時間帯、給湯負荷状態等に基づいて、ヒートポンプ給湯手段2の運転、ガス焚給湯機4の運転、第1電磁弁33の開閉または開度、第2電磁弁34の開閉または開度、及び、循環ポンプ32の運転の各制御を行う。貯湯タンク3の各タンク3a〜3fに設けられた温度センサ35a〜35fの出力は、ヒートポンプ給湯手段2を経由して制御手段5に入力される。 Based on the time zone within a day, the hot water supply load state, etc., the control means 5 operates the heat pump hot water supply means 2, operates the gas water heater 4, opens or closes the first electromagnetic valve 33, or opens the second electromagnetic valve. Control of opening / closing or opening of the valve 34 and operation of the circulation pump 32 is performed. The outputs of the temperature sensors 35 a to 35 f provided in the respective tanks 3 a to 3 f of the hot water storage tank 3 are input to the control means 5 via the heat pump hot water supply means 2.
次に、制御手段5による本発明システム1の運転制御条件の一例について説明する。本実施形態では、1日(22時から翌日の22時までの24時間)を、22時から8時までの主として夜間を含む第1時間帯と、8時から22時までの主として昼間を含む第2時間帯(第1時間帯以外)に区分し、第1時間帯と第2時間帯で制御方法を変えている。 Next, an example of operation control conditions of the system 1 of the present invention by the control means 5 will be described. In this embodiment, one day (24 hours from 22:00 to 22:00 on the next day) includes a first time zone mainly including nighttime from 22:00 to 8:00, and mainly daytime from 8:00 to 22:00. The control method is changed between the first time zone and the second time zone by dividing into second time zones (other than the first time zone).
先ず、夜間の第1時間帯では、第1電磁弁33を閉成し、第2電磁弁34を開成し、ヒートポンプ給湯手段2による給湯を専ら貯湯タンク3への貯湯に使用する。貯湯タンク3の貯湯状態は、温度センサ35a〜35fの出力による各タンク3a〜3fの水温により判定する。貯湯タンク3の全てのタンクがヒートポンプ給湯手段2から給湯された温水で充填されると、ヒートポンプ給湯手段2の運転が停止する。 First, in the first time zone at night, the first electromagnetic valve 33 is closed, the second electromagnetic valve 34 is opened, and hot water supplied from the heat pump hot water supply means 2 is exclusively used for hot water storage in the hot water storage tank 3. The hot water storage state of the hot water storage tank 3 is determined by the water temperature of each of the tanks 3a to 3f based on the outputs of the temperature sensors 35a to 35f. When all the hot water storage tanks 3 are filled with hot water supplied from the heat pump hot water supply means 2, the operation of the heat pump hot water supply means 2 is stopped.
尚、第1時間帯に給湯負荷40での給湯需要(例えば、温水シャワーの使用等)が生じた場合は、ガス焚給湯機4を作動させ、補給水41からの給水を加熱して給湯負荷40へ給湯する。 When a hot water supply demand (for example, use of a hot water shower) occurs at the hot water supply load 40 during the first time zone, the gas water heater 4 is operated to heat the water supplied from the makeup water 41 and supply the hot water supply load. Hot water is supplied to 40.
次に、第1時間帯から昼間の第2時間帯に移行すると、第1電磁弁33を開成し、第2電磁弁34を閉成する。つまり、給湯負荷40での給湯需要に対しては、貯湯タンク3の貯湯量が一定量消費されて所定の第1貯湯量となるまでは、貯湯タンク3からのみ給湯負荷40に給湯する。各タンク3a〜3fは直列に接続されており、最前列のタンク3a側の上部入出水口13から給湯負荷40へ給湯されるが、給湯によって排出された温水は後段のタンクから順次補給されるため、最後列のタンク3f(下部入出水口14側)から順番に前方に向けてタンク内の水温が低下していく。従って、各タンク3a〜3fの温度センサ35a〜35fの検出温度により、貯湯タンク3の貯湯量(温水の残量)が分かる。本実施形態では、最前列から3番目のタンク3cの温度センサ35cの検出温度が所定の設定温度(例えば、50℃)以上であれば、貯湯タンク3の貯湯量(温水の残量)が第1貯湯量以上と判断する。 Next, when shifting from the first time zone to the second time zone during the daytime, the first electromagnetic valve 33 is opened and the second electromagnetic valve 34 is closed. In other words, for hot water supply demand at the hot water supply load 40, hot water is supplied from the hot water storage tank 3 only to the hot water supply load 40 until a certain amount of hot water storage in the hot water storage tank 3 is consumed and reaches a predetermined first hot water storage amount. The tanks 3a to 3f are connected in series, and hot water is supplied from the upper inlet / outlet 13 on the tank 3a side of the front row to the hot water supply load 40, but the hot water discharged by the hot water supply is replenished sequentially from the subsequent tank. The water temperature in the tank gradually decreases from the last row of tanks 3f (lower inlet / outlet 14 side) in order. Accordingly, the amount of hot water stored in the hot water storage tank 3 (the remaining amount of hot water) can be determined from the detected temperatures of the temperature sensors 35a to 35f of the tanks 3a to 3f. In the present embodiment, if the temperature detected by the temperature sensor 35c of the third tank 3c from the front row is equal to or higher than a predetermined set temperature (for example, 50 ° C.), the amount of hot water stored in the hot water storage tank 3 (the remaining amount of hot water) is the first. Judged as 1 or more hot water storage.
引き続き、第2時間帯において給湯負荷40での給湯需要が累積して、貯湯タンク3の貯湯量(温水の残量)が減少して、第1貯湯量を下回ると、つまり、温度センサ35cの出力による検出温度が50℃未満となると、湯切れ防止のため、ヒートポンプ給湯手段2を作動させて、貯湯タンク3からの給湯量の増加の抑制を図る。ここで、給湯負荷40の給湯負荷状態が、ヒートポンプ給湯手段2の給湯能力以下の場合は、貯湯タンク3の貯湯量が増加するため、例えば、最前列から4番目のタンク3dの温度センサ35dの検出温度が所定の設定温度(例えば、50℃)以上であれば、ヒートポンプ給湯手段2の作動を停止する。 Subsequently, when the hot water supply demand at the hot water supply load 40 is accumulated in the second time period and the amount of hot water stored in the hot water storage tank 3 (remaining amount of hot water) decreases and falls below the first hot water storage amount, that is, the temperature sensor 35c When the detected temperature by the output is less than 50 ° C., the heat pump hot water supply means 2 is operated to prevent the hot water supply from the hot water storage tank 3 from increasing in order to prevent hot water from running out. Here, when the hot water supply load state of the hot water supply load 40 is equal to or less than the hot water supply capacity of the heat pump hot water supply means 2, the amount of hot water stored in the hot water storage tank 3 increases. For example, the temperature sensor 35d of the fourth tank 3d from the front row If the detected temperature is equal to or higher than a predetermined set temperature (for example, 50 ° C.), the operation of the heat pump hot water supply means 2 is stopped.
更に、給湯負荷40が高給湯負荷状態に進行すると、ヒートポンプ給湯手段2の運転状態を維持していても、貯湯タンク3の貯湯量(温水の残量)が更に減少して、第1貯湯量より少ない所定の第2貯湯量を下回ると、第2電磁弁34を開成して、ガス焚給湯機4への給水を行うとともにガス焚給湯機4を作動させ、給湯負荷40への給湯を開始する。これにより、高給湯負荷状態におけるヒートポンプ給湯手段2と貯湯タンク3の給湯能力の不足分をガス焚給湯機4で補い、湯切れを防止して安定した給湯を行うことができる。尚、本実施形態では、最前列から2番目のタンク3bの温度センサ35bの検出温度が所定の設定温度(例えば、50℃)以下になると、貯湯タンク3の貯湯量(温水の残量)が第2貯湯量以下と判断する。尚、給湯負荷40の給湯負荷状態が、ヒートポンプ給湯手段2とガス焚給湯機4の合計の給湯能力以下の場合は、貯湯タンク3の貯湯量が増加するため、例えば、最前列から3番目のタンク3cの温度センサ35cの検出温度が所定の設定温度(例えば、50℃)以上であれば、ガス焚給湯機4の作動を停止する。 Further, when the hot water supply load 40 advances to a high hot water supply load state, even if the operation state of the heat pump hot water supply means 2 is maintained, the amount of hot water stored in the hot water storage tank 3 (remaining amount of hot water) further decreases, and the first hot water storage amount. When less than a predetermined second hot water storage amount, the second solenoid valve 34 is opened to supply water to the gas water heater 4 and to operate the gas water heater 4 to start hot water supply to the hot water load 40. To do. Thereby, the shortage of the hot water supply capacity of the heat pump hot water supply means 2 and the hot water storage tank 3 in the high hot water supply load state can be compensated for by the gas fired water heater 4, and hot water can be prevented from running out and stable hot water supply can be performed. In the present embodiment, when the temperature detected by the temperature sensor 35b of the second tank 3b from the front row falls below a predetermined set temperature (for example, 50 ° C.), the amount of hot water stored in the hot water storage tank 3 (remaining amount of hot water) is reduced. It is determined that the amount is less than the second hot water storage amount. In addition, when the hot water supply load state of the hot water supply load 40 is less than the total hot water supply capacity of the heat pump hot water supply means 2 and the gas fired hot water supply device 4, the amount of hot water stored in the hot water storage tank 3 increases. When the temperature detected by the temperature sensor 35c of the tank 3c is equal to or higher than a predetermined set temperature (for example, 50 ° C.), the operation of the gas water heater 4 is stopped.
更に、給湯負荷40の高給湯負荷状態によって、貯湯タンク3の貯湯量(温水の残量)が更に減少して、湯切れ状態直前となると、つまり、最前列のタンク3aの温度センサ35aの検出温度が所定の設定温度(例えば、50℃)以下になると、低温の温水が給湯負荷40に給湯されるのを防止すべく、第1電磁弁33を閉成して、ガス焚給湯機4のみで給湯負荷40への給湯を行う。 Further, when the hot water supply load 40 is in a high hot water supply load state, the amount of hot water stored in the hot water storage tank 3 (remaining amount of hot water) is further reduced and immediately before the hot water runs out, that is, the detection by the temperature sensor 35a of the tank 3a in the front row. When the temperature falls below a predetermined set temperature (for example, 50 ° C.), the first solenoid valve 33 is closed to prevent only the hot water of low temperature from being supplied to the hot water supply load 40, and only the gas water heater 4 is used. The hot water supply to the hot water supply load 40 is performed.
次に、時間帯に関係なく、給湯負荷40が、給湯負荷40からの還流水を給湯復路である管路24を介してガス焚給湯機4に戻す循環負荷の場合には、循環ポンプ32及びガス焚給湯機4が作動して、当該循環負荷への給湯を行い、ガス焚給湯機4が当該循環負荷の循環路上での放熱分(熱消費分)を補うようにする。 Next, in the case where the hot water supply load 40 is a circulation load that returns the reflux water from the hot water supply load 40 to the gas-fired water heater 4 via the pipe 24 that is a hot water supply return path regardless of the time zone, the circulation pump 32 and The gas fired water heater 4 operates to supply hot water to the circulation load, and the gas fired water heater 4 compensates for the heat radiation (heat consumption) on the circulation path of the circulation load.
〈第2実施形態〉
次に、本発明システムの第2実施形態について説明する。図2は、本発明システムの第2実施形態における概略のシステム構成図である。尚、図中の破線は、各種制御用の信号線を示し、第1実施形態と同じ構成要素には同じ符号を付して説明する。
Second Embodiment
Next, a second embodiment of the system of the present invention will be described. FIG. 2 is a schematic system configuration diagram in the second embodiment of the system of the present invention. In addition, the broken line in a figure shows the signal line for various control, and attaches | subjects and demonstrates the same code | symbol to the same component as 1st Embodiment.
図2に示すように、第2実施形態に係る本発明システム10は、ヒートポンプ給湯手段2、貯湯タンク3、補助給湯手段であるガス焚給湯機4、補助貯湯タンク6、及び、本発明システム10の運転を制御する制御手段5を備えて構成される。更に、ヒートポンプ給湯手段2と貯湯タンク3とガス焚給湯機4と補助貯湯タンク6と給湯負荷40の相互間が複数の管路20〜25、61〜64で接続されている。第1実施形態との相違点は、ガス焚給湯機4と給湯負荷40の間に、ガス焚給湯機4から給湯された温水を貯湯する補助貯湯タンク6が介在している点である。尚、本実施形態では、補助貯湯タンク6として単槽構造のものを例示しているが、これに限定されるものではない。 As shown in FIG. 2, the present invention system 10 according to the second embodiment includes a heat pump hot water supply means 2, a hot water storage tank 3, a gas water heater 4 that is an auxiliary hot water supply means, an auxiliary hot water storage tank 6, and the present invention system 10. And a control means 5 for controlling the operation. Further, the heat pump hot water supply means 2, the hot water storage tank 3, the gas water heater 4, the auxiliary hot water storage tank 6, and the hot water supply load 40 are connected to each other by a plurality of pipelines 20 to 25 and 61 to 64. The difference from the first embodiment is that an auxiliary hot water storage tank 6 for storing hot water supplied from the gas water heater 4 is interposed between the gas water heater 4 and the hot water load 40. In addition, in this embodiment, although the thing of the single tank structure is illustrated as the auxiliary hot water storage tank 6, it is not limited to this.
具体的には、ヒートポンプ給湯手段2の出水口11と給湯負荷40間が給湯往路である管路20で接続され、ヒートポンプ給湯手段2の入水口12と補給水(上水道等)41間が給水路である管路21で接続され、貯湯タンク3の上部入出水口13が管路20に、貯湯タンク3の下部入出水口14が管路21に、夫々接続されている。給湯往路である管路20上の、貯湯タンク3の上部入出水口13との接続個所より下流側(給湯負荷40側)に、温度調整用の3方弁30が介装され、給水路である管路21が、貯湯タンク3の下部入出水口14との接続個所より上流側(補給水41側)で分岐して、3方弁30に接続している。更に、管路20上の貯湯タンク3の上部入出水口13との接続点と3方弁30の中間に第1電磁弁33が介装されている。温度調整用の3方弁30は、3方弁30より下流側の管路20に設けられた温度センサ31の検出温度に基づいて、管路21側からの給水量を調整する。以上、第1実施形態と同じ構成である。 Specifically, the water outlet 11 of the heat pump hot water supply means 2 and the hot water supply load 40 are connected by a pipe 20 that is a hot water supply forward path, and the water supply path is between the water inlet 12 of the heat pump hot water supply means 2 and makeup water (such as waterworks) 41. The upper inlet / outlet 13 of the hot water storage tank 3 is connected to the pipe 20, and the lower inlet / outlet 14 of the hot water storage tank 3 is connected to the pipe 21, respectively. A three-way valve 30 for temperature adjustment is provided downstream from the connection point with the upper inlet / outlet water inlet 13 of the hot water storage tank 3 on the pipe line 20 which is a hot water supply outward path, and is a water supply path. A pipe 21 branches on the upstream side (supply water 41 side) from the connection point with the lower inlet / outlet water inlet 14 of the hot water storage tank 3 and is connected to the three-way valve 30. Further, a first electromagnetic valve 33 is interposed between the connection point of the hot water storage tank 3 on the pipe line 20 with the upper inlet / outlet water inlet 13 and the three-way valve 30. The three-way valve 30 for temperature adjustment adjusts the amount of water supplied from the pipe 21 side based on the temperature detected by the temperature sensor 31 provided in the pipe 20 downstream of the three-way valve 30. The configuration is the same as that of the first embodiment.
更に、ガス焚給湯機4の出水口15が、補助貯湯タンク6の上部に設けられた入水口51と管路61を介して接続している。ガス焚給湯機4の入水口16が、補助貯湯タンク6の下部に設けられた出水口52と、循環ポンプ36を介装した管路62を介して接続している。循環ポンプ36は、補助貯湯タンク6の水温を計測する温度センサ37の検出温度に基づいて作動する。補助貯湯タンク6の上部に設けられた出水口53が、給湯往路である管路20と、3方弁30より下流側において接続している。また、循環ポンプ32が介装された管路63が、管路20の3方弁30より下流側部分と並列に設けられており、循環ポンプ32は給湯負荷40が循環負荷の場合に作動する。補助貯湯タンク6の下部に設けられた2つの入水口54,55の内の一方の入水口54と給湯負荷40間が、給湯復路である管路24で接続され、他方の入水口55は、給水路である管路21の3方弁30への分岐点より上流側と、第2電磁弁34が介装された管路64を介して接続されている。以上、第1実施形態と相違する構成部分である。 Further, the water outlet 15 of the gas water heater 4 is connected to a water inlet 51 provided in the upper part of the auxiliary hot water storage tank 6 via a pipe 61. A water inlet 16 of the gas water heater 4 is connected to a water outlet 52 provided in the lower part of the auxiliary hot water storage tank 6 via a pipe line 62 having a circulation pump 36 interposed therebetween. The circulation pump 36 operates based on the temperature detected by the temperature sensor 37 that measures the water temperature of the auxiliary hot water storage tank 6. A water outlet 53 provided in the upper part of the auxiliary hot water storage tank 6 is connected to the pipe line 20 which is a hot water supply outbound path on the downstream side of the three-way valve 30. Further, a pipe line 63 in which a circulation pump 32 is interposed is provided in parallel with a part downstream of the three-way valve 30 of the pipe line 20, and the circulation pump 32 operates when the hot water supply load 40 is a circulation load. . Between one of the two water inlets 54 and 55 provided at the lower part of the auxiliary hot water storage tank 6 and the hot water supply load 40 is connected by a pipeline 24 which is a hot water supply return path, and the other water inlet 55 is The upstream side of the branch line 21 to the three-way valve 30 of the pipeline 21 that is a water supply channel is connected via a pipeline 64 in which the second electromagnetic valve 34 is interposed. As mentioned above, it is a component part different from 1st Embodiment.
尚、図示していないが、各管路20〜25、61〜64には、夫々、開閉弁(2方弁)、逆止弁、減圧弁、定流量弁、安全弁、自動空気抜き弁等の内、適宜必要なものが介装されている。また、ヒートポンプ給湯手段2の入水口12の内側にも、図示しないが、開閉弁や循環ポンプが設けられている。また、ヒートポンプ給湯手段2と貯湯タンク3とガス焚給湯機4は、第1実施形態と同じであるので、重複する説明は割愛する。 Although not shown, each of the pipes 20 to 25 and 61 to 64 includes an on-off valve (two-way valve), a check valve, a pressure reducing valve, a constant flow valve, a safety valve, an automatic air vent valve, and the like. Necessary items are provided as appropriate. Although not shown, an open / close valve and a circulation pump are also provided inside the water inlet 12 of the heat pump hot water supply means 2. Moreover, since the heat pump hot-water supply means 2, the hot water storage tank 3, and the gas fired hot water supply device 4 are the same as 1st Embodiment, the overlapping description is omitted.
制御手段5は、1日の内の時間帯、給湯負荷状態等に基づいて、ヒートポンプ給湯手段2の運転、ガス焚給湯機4の運転、第1電磁弁33の開閉または開度、第2電磁弁34の開閉または開度、及び、循環ポンプ32の運転の各制御を行う点で、第1実施形態と同じであり、貯湯タンク3の各タンク3a〜3fに設けられた温度センサ35a〜35fの出力は、ヒートポンプ給湯手段2を経由して制御手段5に入力される。また、制御手段5による本発明システム10の運転制御条件も、第1実施形態と同じである。第1実施形態との実質的な相違点は、夜間の第1時間帯において給湯負荷40で給湯需要が生じた場合、及び、第2時間帯において給湯負荷40が高給湯負荷状態になり、貯湯タンク3の貯湯量(温水の残量)が第2貯湯量を下回った場合に、給湯負荷40に対してガス焚給湯機4から直接給湯されるのではなく、補助貯湯タンク6に貯湯されている温水が給湯される点である。この構成により、給湯負荷40が瞬間的に高給湯負荷状態になって、ガス焚給湯機4の起動が間に合わない場合等の急激な負荷変動時においても、瞬時に補助貯湯タンク6から給湯負荷40に対して給湯されるため、第1実施形態に比べてより安定した給湯が担保される。 Based on the time zone within a day, the hot water supply load state, etc., the control means 5 operates the heat pump hot water supply means 2, operates the gas water heater 4, opens or closes the first electromagnetic valve 33, or opens the second electromagnetic valve. The temperature sensors 35a to 35f provided in the respective tanks 3a to 3f of the hot water storage tank 3 are the same as those of the first embodiment in that each control of opening / closing or opening of the valve 34 and the operation of the circulation pump 32 is performed. Is input to the control means 5 via the heat pump hot water supply means 2. Moreover, the operation control conditions of the system 10 of the present invention by the control means 5 are the same as those in the first embodiment. A substantial difference from the first embodiment is that when a hot water supply demand is generated at the hot water supply load 40 in the first time zone at night and when the hot water supply load 40 is in a high hot water supply load state in the second time zone, When the amount of hot water stored in the tank 3 (remaining amount of hot water) falls below the second hot water storage amount, the hot water supply load 40 is not directly supplied with hot water from the gas-fired water heater 4, but is stored in the auxiliary hot water storage tank 6. This is the point where hot water is supplied. With this configuration, even when the hot water supply load 40 instantaneously becomes a high hot water supply load state and the start of the gas fired water heater 4 is not in time, the hot water supply load 40 is instantaneously supplied from the auxiliary hot water storage tank 6. Therefore, more stable hot water supply is ensured as compared to the first embodiment.
次に、本発明システムの別実施形態について説明する。 Next, another embodiment of the system of the present invention will be described.
〈1〉上記各実施形態において、ヒートポンプ給湯手段2としてCO2ヒートポンプを想定して説明したが、CO2ヒートポンプは効率及び温水の加熱温度が高い点で有利ではあるが、ヒートポンプ給湯手段2は、CO2ヒートポンプに限定されるものではない。 <1> In each of the above embodiments, a CO 2 heat pump has been described as the heat pump hot water supply means 2, but the CO 2 heat pump is advantageous in terms of efficiency and high heating temperature, but the heat pump hot water supply means 2 It is not limited to a CO 2 heat pump.
〈2〉上記各実施形態において、貯湯タンク3として6台のタンク3a〜3fを直列に配列して構成されたものを例示したが、貯湯タンク3の構成及びタンク数は、上記各実施形態の構成に限定されるものではない。例えば、貯湯タンク3として単槽構造のものを利用しても構わない。 <2> In each of the above embodiments, the hot water storage tank 3 is configured by arranging six tanks 3a to 3f in series. However, the configuration and the number of tanks of the hot water storage tank 3 are the same as those of the above embodiments. The configuration is not limited. For example, a single tank structure may be used as the hot water storage tank 3.
〈3〉上記各実施形態において例示した補助給湯手段としてのガス焚給湯機4に代えて、油焚き給湯機を利用しても構わない。また、補助給湯手段は、必ずしも真空式ボイラに限定されるものではない。 <3> An oil-fired water heater may be used in place of the gas-fired water heater 4 as the auxiliary hot water supply means exemplified in the above embodiments. Further, the auxiliary hot water supply means is not necessarily limited to the vacuum boiler.
〈4〉上記各実施形態において例示した制御手段5による本発明システム1の運転制御条件は、一例であり、必ずしも上記各実施形態で例示した条件に限定されるものではない。例えば、第1時間帯と第2時間帯の定義も上記各実施形態のものに限定されない。また、第1貯湯量及び第2貯湯量の判定に使用する温度センサの検出温度も例えば50℃に限定されるものではない。更に、第2時間帯において作動したヒートポンプ給湯手段2を停止させる条件も、例えば、最前列から5番目のタンク3eの温度センサ35eの検出温度が所定の設定温度(例えば、50℃)以上としてもよく、或いは、第2時間帯において作動したガス焚給湯機4を停止させる条件も、例えば、最前列から4番目のタンク3dの温度センサ35dの検出温度が所定の設定温度(例えば、50℃)以上としてもよい。更に、第1貯湯量及び第2貯湯量の判定に使用する温度センサの設置されたタンクの位置も、上記各実施形態では、夫々、最前列から3番目のタンク3cの温度センサ35cと、最前列から2番目のタンク3bの温度センサ35bとしたが、例えば、夫々のタンクの位置を1台ずつ後段にずらしても構わない。 <4> The operation control conditions of the system 1 of the present invention by the control means 5 illustrated in the above embodiments are merely examples, and are not necessarily limited to the conditions illustrated in the above embodiments. For example, the definitions of the first time zone and the second time zone are not limited to those in the above embodiments. Moreover, the detection temperature of the temperature sensor used for determination of the 1st amount of hot water storage and the 2nd amount of hot water storage is not limited to 50 degreeC, for example. Furthermore, the condition for stopping the heat pump hot water supply means 2 that has been operated in the second time zone may be, for example, that the detected temperature of the temperature sensor 35e of the fifth tank 3e from the front row is equal to or higher than a predetermined set temperature (for example, 50 ° C) For example, the condition for stopping the gas water heater 4 that has been operated in the second time zone is, for example, that the temperature detected by the temperature sensor 35d of the fourth tank 3d from the front row is a predetermined set temperature (for example, 50 ° C.). It is good also as above. Further, the position of the tank in which the temperature sensor used for the determination of the first hot water storage amount and the second hot water storage amount is also the same as the temperature sensor 35c of the third tank 3c from the front row, respectively, in the above embodiments. Although the temperature sensor 35b of the second tank 3b from the front row is used, for example, the position of each tank may be shifted to the rear stage one by one.
〈5〉また、上記各実施形態で説明した本発明システム1、10の構成は、図1及び図2に夫々例示する構成に限定されるものではなく、本発明の特許請求の範囲で示される技術的範囲内において適宜変更可能である。従って、図1及び図2に例示した管路構成は一例であり、適宜変更可能である。例えば、給湯負荷40が循環負荷でない場合は、ガス焚給湯機4の入水口16と給湯負荷40間を給湯復路である管路24で接続する必要はない。 <5> In addition, the configurations of the systems 1 and 10 of the present invention described in the above embodiments are not limited to the configurations illustrated in FIGS. 1 and 2, respectively, and are shown in the claims of the present invention. It can be appropriately changed within the technical scope. Therefore, the pipe line configuration illustrated in FIGS. 1 and 2 is an example, and can be changed as appropriate. For example, when the hot water supply load 40 is not a circulation load, it is not necessary to connect the inlet 16 of the gas water heater 4 and the hot water supply load 40 with the pipe line 24 that is a hot water supply return path.
〈6〉更に、上記各実施形態では、制御手段5がヒートポンプ給湯手段2とガス焚給湯機4に対して独立して存在する構成としたが、制御手段5を、例えば、ヒートポンプ給湯手段2の運転制御装置内に設けるようにしても構わない。 <6> Furthermore, in each said embodiment, although the control means 5 was set as the structure which exists independently with respect to the heat pump hot-water supply means 2 and the gas-fired water heater 4, the control means 5 is set to the heat pump hot-water supply means 2, for example. You may make it provide in an operation control apparatus.
〈7〉また、上記各実施形態において例示したヒートポンプ給湯手段2の圧縮機の定格出力及び加熱能力、貯湯タンク3の総容量、ガス焚給湯機4の缶体出力等の数値は、説明の理解のための例示であり、これらの数値に限定されるものではない。 <7> In addition, numerical values such as the rated output and heating capacity of the compressor of the heat pump hot water supply means 2 exemplified in the above embodiments, the total capacity of the hot water storage tank 3, and the can output of the gas fired water heater 4 are understood. However, the present invention is not limited to these numerical values.
本発明に係る給湯システムは、ヒートポンプ式の給湯システムに利用でき、ヒートポンプ式の給湯システムに必要な給湯能力を高いエネルギ効率を維持して確保可能な給湯システムを提供することができる。 The hot water supply system according to the present invention can be used in a heat pump hot water supply system, and can provide a hot water supply system that can ensure the hot water supply capacity necessary for the heat pump hot water supply system while maintaining high energy efficiency.
1、10: 本発明に係る給湯システム
2: ヒートポンプ給湯手段
3: 貯湯タンク
3a〜3f: タンク
4: ガス焚給湯機(補助給湯手段)
5: 制御手段
6: 補助貯湯タンク
11: ヒートポンプ給湯手段の出水口
12: ヒートポンプ給湯手段の入水口
13: 貯湯タンクの上部入出水口
14: 貯湯タンクの下部入出水口
15: ガス焚給湯機の出水口
16: ガス焚給湯機の入水口
20: 管路(給湯往路)
21: 管路(給水路)
22、23、25: 管路
24: 管路(給湯復路)
30: 3方弁
31: 温度センサ
32: 循環ポンプ
33: 第1電磁弁
34: 第2電磁弁
35a〜35f: 温度センサ
36: 循環ポンプ
37: 温度センサ
40: 給湯負荷
41: 補給水
51: 補助貯湯タンクの上部入水口
52: 補助貯湯タンクの下部出水口
53: 補助貯湯タンクの上部出水口
54、55: 補助貯湯タンクの下部入水口
61〜64: 管路
DESCRIPTION OF SYMBOLS 1, 10: Hot-water supply system which concerns on this invention 2: Heat pump hot-water supply means 3: Hot water storage tank 3a-3f: Tank 4: Gas fired water heater (auxiliary hot-water supply means)
5: Control means 6: Auxiliary hot water storage tank 11: Water outlet of heat pump hot water supply means 12: Water inlet of heat pump hot water means 13: Upper water inlet / outlet of hot water storage tank 14: Lower water inlet / outlet of hot water storage tank 15: Water outlet of gas water heater 16: Gas water heater inlet 20: Pipe line (outward hot water supply)
21: Pipeline (water supply channel)
22, 23, 25: pipeline 24: pipeline (hot water return)
30: Three-way valve 31: Temperature sensor 32: Circulation pump 33: First electromagnetic valve 34: Second electromagnetic valve 35a to 35f: Temperature sensor 36: Circulation pump 37: Temperature sensor 40: Hot water supply load 41: Supply water 51: Auxiliary Upper water inlet of hot water storage tank 52: Lower water outlet of auxiliary hot water storage tank 53: Upper water outlet of auxiliary hot water storage tank 54, 55: Lower water inlet of auxiliary hot water storage tank 61-64: Pipe line
Claims (7)
前記貯湯タンクから前記給湯負荷への給湯往路に対して、直接或いは補助貯湯タンクを介して給湯可能なガス焚または油焚きによる補助給湯手段を備えることを特徴とする給湯システム。 A heat pump hot water supply means for heating and supplying hot water by exchanging heat and heat from the condenser of the heat pump circuit and a hot water storage tank, and hot water heated by the heat pump hot water supply means is stored in the hot water storage tank to store the hot water from the hot water storage tank. A hot water supply system configured to be capable of hot water supply with respect to a hot water supply load,
A hot water supply system comprising auxiliary hot water supply means by gas tank or oiling that can supply hot water directly from the hot water storage tank to the hot water supply load or through the auxiliary hot water storage tank.
1日の内の前記第1時間帯以外の第2時間帯に、前記貯湯タンクの貯湯量が所定の第1貯湯量以上である場合は、前記貯湯タンクからのみ前記給湯負荷へ給湯し、
前記第2時間帯に、前記貯湯タンクの貯湯量が前記第1貯湯量を下回ると、前記ヒートポンプ給湯手段による温水加熱を追加し、
前記第2時間帯に、前記貯湯タンクの貯湯量が前記第1貯湯量より少ない所定の第2貯湯量を下回ると、前記補助給湯手段による給湯を追加することを特徴とする請求項1に記載の給湯システム。 A predetermined amount of hot water is heated by the heat pump hot water supply means and stored in the hot water storage tank in a first time zone mainly including nighttime when a low hot water supply load state is reached within a day,
When the amount of hot water stored in the hot water storage tank is greater than or equal to a predetermined first hot water storage amount in a second time zone other than the first time zone in one day, hot water is supplied only from the hot water storage tank to the hot water supply load,
When the amount of hot water stored in the hot water storage tank falls below the first amount of hot water stored in the second time zone, hot water heating by the heat pump hot water supply means is added,
The hot water supply by the auxiliary hot water supply means is added when the hot water storage amount of the hot water storage tank falls below a predetermined second hot water storage amount that is smaller than the first hot water storage amount during the second time period. Hot water system.
前記貯湯タンクの最後列のタンクの底部が、前記ヒートポンプ給湯手段の入水口に連通し、前記貯湯タンクの最前列のタンクの上部が、前記ヒートポンプ給湯手段の出水口に連通していることを特徴とする請求項1〜3の何れか1項に記載の給湯システム。 The hot water storage tank is configured by arranging a plurality of tanks in series, and connecting the bottom part of the front stage and the upper part of the rear stage of two continuous tanks,
The bottom of the last row of the hot water storage tanks communicates with a water inlet of the heat pump hot water supply means, and the upper part of the front row of the hot water storage tanks communicates with a water outlet of the heat pump hot water supply means. The hot water supply system according to any one of claims 1 to 3.
前記貯湯タンクの最後列のタンクの底部が、前記ヒートポンプ給湯手段の入水口に連通し、前記貯湯タンクの最前列のタンクの上部が、前記ヒートポンプ給湯手段の出水口に連通し、
前記貯湯タンクの貯湯量と前記第1貯湯量との大小比較が、前記複数のタンクの最前列から所定番目のタンクに設けられた温度センサの検出温度により判定され、
前記貯湯タンクの貯湯量と前記第2貯湯量との大小比較が、前記所定番目のタンクより前方のタンクに設けられた温度センサの検出温度により判定されることを特徴とする請求項2または3に記載の給湯システム。 The hot water storage tank is configured by arranging a plurality of tanks in series, and connecting the bottom part of the front stage and the upper part of the rear stage of two continuous tanks,
The bottom of the tank in the last row of the hot water storage tank communicates with the water inlet of the heat pump hot water supply means, and the upper part of the tank in the front row of the hot water storage tank communicates with the water outlet of the heat pump hot water supply means,
The magnitude comparison between the hot water storage amount of the hot water storage tank and the first hot water storage amount is determined by the detected temperature of a temperature sensor provided in a predetermined tank from the front row of the plurality of tanks,
The size comparison between the hot water storage amount of the hot water storage tank and the second hot water storage amount is determined by a temperature detected by a temperature sensor provided in a tank ahead of the predetermined tank. Hot water supply system as described in.
前記給湯負荷の循環路上での放熱分を、前記補助給湯手段からの給湯で補うことを特徴とする請求項1〜5の何れか1項に記載の給湯システム。 A hot water return path from the hot water supply load communicates with a water inlet of the auxiliary hot water supply means,
The hot water supply system according to any one of claims 1 to 5, wherein the amount of heat radiation on the circulation path of the hot water supply load is supplemented by hot water supplied from the auxiliary hot water supply means.
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JP2007057111A (en) * | 2005-08-22 | 2007-03-08 | Nippon Thermoener Co Ltd | Hybrid hot water supply system |
JP2009097804A (en) * | 2007-10-17 | 2009-05-07 | Panasonic Electric Works Co Ltd | Water heating system |
JP2010025499A (en) * | 2008-07-23 | 2010-02-04 | Nippon Thermoener Co Ltd | Hybrid hot-water supply system |
JP2010127550A (en) * | 2008-11-28 | 2010-06-10 | Nishimatsu Constr Co Ltd | Heating hot water supply system, energy saving and method for reducing amount of emission of warming gas |
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WO2016189663A1 (en) * | 2015-05-26 | 2016-12-01 | 三菱電機株式会社 | Heat pump hot water supply system |
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JP2007057111A (en) * | 2005-08-22 | 2007-03-08 | Nippon Thermoener Co Ltd | Hybrid hot water supply system |
JP4528226B2 (en) * | 2005-08-22 | 2010-08-18 | 株式会社日本サーモエナー | Hybrid hot water supply system |
JP2009097804A (en) * | 2007-10-17 | 2009-05-07 | Panasonic Electric Works Co Ltd | Water heating system |
JP2010025499A (en) * | 2008-07-23 | 2010-02-04 | Nippon Thermoener Co Ltd | Hybrid hot-water supply system |
JP2010127550A (en) * | 2008-11-28 | 2010-06-10 | Nishimatsu Constr Co Ltd | Heating hot water supply system, energy saving and method for reducing amount of emission of warming gas |
JP2011117647A (en) * | 2009-12-02 | 2011-06-16 | Nishimatsu Constr Co Ltd | Operational availability reducing system for existing boiler |
WO2016189663A1 (en) * | 2015-05-26 | 2016-12-01 | 三菱電機株式会社 | Heat pump hot water supply system |
JPWO2016189663A1 (en) * | 2015-05-26 | 2018-01-11 | 三菱電機株式会社 | Heat pump hot water supply system |
AU2015395825B2 (en) * | 2015-05-26 | 2018-11-08 | Mitsubishi Electric Corporation | Heat pump hot-water supply system |
JP2019045145A (en) * | 2018-12-26 | 2019-03-22 | パーパス株式会社 | Hot water supply system, hot water supply program and hot water supply method |
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