JP5930299B2 - Hotel room allocation support device - Google Patents

Description

  The present invention relates to a system that supports room allocation in a hotel or the like, and more particularly to a system that supports room allocation in consideration of a heat exchanger system that is responsible for cooling and heating a plurality of rooms for energy saving.

  In accommodation facilities such as hotels and inns (hereinafter, “hotel” will be described as a typical example), rooms are allocated to guests every day. Many hotels use a computer reservation system to manage the number of rooms required on the day. Usually, when room allocation is performed for a hotel, the room allocation is performed in accordance with a guest's desire, a manual of the hotel, and various circumstances. Several systems for efficiently performing such room allocation have also been presented.

  For example, Patent Document 1 discloses a system that allocates a room closest to a scheduled action place on a use applicant's use date.

JP 2006-126944 A

  Here, a hotel of a certain scale or more is equipped with an air conditioning system composed of a plurality of heat exchanger systems. One heat exchanger system is composed of an outdoor unit that is one heat exchanger, and an indoor unit installed in each of a plurality of rooms that the outdoor unit is responsible for. Control of operation and stop of one heat exchanger system is performed by control of operation and stop of the heat exchanger (outdoor unit) of the heat exchanger system.

  FIGS. 24 (a) and 24 (b) are diagrams showing the relationship between the room allocation and the operation status of the heat exchanger system in a hotel equipped with a plurality of heat exchanger systems as a conventional example. (A) is the figure which showed typically the room structure of a hotel, and the heat exchanger system structure. (B) is the figure which showed the condition which performed room allocation in the structure of (a).

  In FIG. 24 (a), the number of rooms on each floor of the five layers is 10, 10, 12, 14, and 14 in order from the upper layer to the lower layer, and the total number of rooms is 60. In this example, each floor is one heat exchanger system, and one heat exchanger (outdoor unit) is responsible for indoor units in all rooms on the floor. The heat exchangers are HP1, HP2, HP3, HP4, and HP5 in order from the upper layer to the lower layer. In this example, the energy usage of the five heat exchanger systems is the same, for example, 2 kW / h. The maximum energy consumption when all heat exchanger systems are operating is 10 kW / h.

  In this specification, “energy consumption” is a measure of energy consumption when the heat exchanger system, that is, an outdoor unit is operated, and is a theoretical value. This theoretical value is calculated based on the rating of the heat exchanger and past performance values (for example, different for each season or special period). This theoretical value is a value that is considered to be appropriate as a predicted value of energy usage in a predetermined season or period. In this specification, the difference in energy usage due to the operation / stop of each indoor unit is not considered.

  FIG. 24B is a diagram showing a room allocation situation when the number of used rooms is 45 (the used room rate is 75% and the vacancy rate is 25%). The shaded area is the room assigned. In this case, since room allocation is performed on all floors, it is necessary to operate (ON) all heat exchanger systems. Each heat exchanger must be operated even when one of a plurality of reception rooms is used even if the other reception room is empty. In other words, even when the usage rate is 75%, the total energy usage of the heat exchanger system is 100% at the maximum.

  Here, regarding the heat exchanger HP2, seven of the ten rooms are used. If these seven rooms are transferred to vacant rooms on the lower floor, all the rooms in charge of the heat exchanger HP2 are vacant, so the heat exchanger HP2 can be stopped. This reduces the total energy usage from 100% to 80%. Conventionally, hotel room assignment has not been performed in consideration of the relationship between such a heat exchanger system and its host room.

  In view of the current situation as described above, the present invention provides a room allocation support device that supports room allocation in consideration of the relationship between a plurality of heat exchanger systems and their holding rooms in order to save energy in a hotel or the like. The purpose is to do.

In order to achieve the above object, the present invention provides the following configurations.
According to a first aspect of the room allocation support apparatus in a hotel or the like according to the present invention, each of the plurality of heat exchanger systems is responsible for one or a plurality of rooms, and the operation and stop are controlled for each heat exchanger system. A room assignment support device for supporting room assignment in a hotel or the like equipped with an exchange system,
(A) a heat exchanger system registration table in which each heat exchanger system is stored in advance in association with the number and location of the rooms in the heat exchanger system;
(B) by sequentially operating a plurality of full stop state of the heat exchanger system lines running order until the entire operating state and is determined in advance, when sequentially by running the heat exchanger system in accordance with the system operation sequence A system operation characteristic table in which the number of rooms used by accumulating the number of rooms in each heat exchanger system is stored in advance in association with the system operation order;
(C) means for acquiring the number of reserved rooms on the day of room allocation;
(D) The number of used rooms corresponding to the acquired number of reserved rooms is detected from the system operation characteristic table, and the heat exchanger system to be operated in the detected number of used rooms and the heat exchanger system to be stopped are based on the order of system operation. Means to decide
(E) means for acquiring the determined location of the assigned room of the heat exchanger system to be operated from the heat exchanger system registration table and determining the room as an assignable room.

In the first aspect, when the energy usage amount of each of the plurality of heat exchanger systems is the same and the number of the respective handling rooms is different, the system operation order is determined in the order of the number of the handling rooms. It is preferable that it exists.

In the first aspect, in the heat exchanger system registration table, each heat exchanger system and the energy usage amount of the heat exchanger system are further associated with each other and stored in advance.
When the energy usage amount of each of the plurality of heat exchanger systems is different and the number of the respective rooms is the same, it is preferable that the order of operation of the system is determined in ascending order of the energy usage amount.

A first aspect of a room allocation support apparatus in a hotel or the like according to the present invention is such that each of a plurality of heat exchanger systems has a predetermined energy consumption, is responsible for a plurality of rooms, and is controlled for operation and stop for each heat exchanger system. A room allocation support device for supporting room allocation in a hotel or the like having the plurality of heat exchanger systems,
(A) Among the plurality of heat exchanger systems, those having the same number of rooms and the same amount of energy use are defined as one system group, and the plurality of heat exchange systems are divided into one or more system groups. A heat exchanger system registration table prestored in association with each heat exchanger system, the number and location of the rooms in the heat exchanger system, and the energy usage of the heat exchanger system;
The (b) all permutations strains operation order of up are sequentially operated from multiple full stop state of the heat exchanger system to a full operational state, dealing with heat exchanger system included in one of the family as the same For each of the determined system operation order, and the number of rooms used in accumulating the number of service rooms of each heat exchanger system when sequentially operating each heat exchanger system according to the system operation order, An energy usage accumulated value obtained by accumulating the energy usage of the heat exchanger system, and a system operation characteristic table for each system operation order stored in advance in association with the system operation order;
(C) means for acquiring reservation information including the number of reserved rooms on the day of room allocation;
(D1) means for detecting the number of used rooms corresponding to the acquired number of reserved rooms from all the system operation characteristic tables, respectively, and acquiring the accumulated energy usage amount in the detected number of used rooms;
(D2) by comparing the energy consumption cumulative value of the acquired system running each sequence, means for energy consumption accumulated value to extract one or more systems operating order is minimal,
(D3) in response to extracted the one or more from among the strains running order one system operation order is determined, the determined system operating order, the heat exchanger system and to run before Symbol used rooms Means for determining a heat exchanger system to be stopped based on the determined system operation order;
(E) means for acquiring the determined location of the assigned room of the heat exchanger system to be operated from the heat exchanger system registration table and determining the room as an assignable room.

In the means of (d1) of the second aspect, instead of detecting the number of used rooms from all the system operation characteristic tables, the corresponding use from a plurality of system operation characteristic tables selected as comparison targets. It is preferable to detect the number of rooms and acquire the accumulated energy usage amount in the detected number of used rooms.

In the means of (c) of the second aspect, when the reservation information includes information on a designated room, means for obtaining a heat exchanger system responsible for the designated room from the heat exchanger system registration table further Have
It is preferable to select only the system operation characteristic table in the system operation order starting from the acquired heat exchanger system as a comparison target.

The room allocation support apparatus in a hotel or the like according to the present invention considers the relationship between each of the plurality of heat exchanger systems provided in the hotel or the like and each of the host rooms, so that the number of heat exchanger systems that can be stopped is increased as much as possible. Is to do. Thereby, energy saving can be aimed at. The most basic concept is a system in which room allocation is performed for all the rooms in one heat exchanger system, and then room allocation is performed for the rooms in another heat exchanger system. Thereby, it becomes possible to operate the heat exchanger system without waste. Conventionally, since room allocation has been performed regardless of the heat exchanger system, a room for a host room of another heat exchanger system, even though there are still vacancies in a plurality of host rooms of one heat exchanger system. An allocation occurred. In such a conventional system, two heat exchanger systems are to be operated instead of one heat exchanger system.
More preferably, when the number of rooms in each of the plurality of heat exchanger systems is different (however, the amount of energy used is the same), by assigning a room from a heat exchanger system having a large number of rooms, any use can be made. Even in the number of rooms (cumulative number of rooms in charge), the number of operating heat exchanger systems can be minimized.
More preferably, when each of the plurality of heat exchanger systems has different energy usage (however, the number of rooms in charge is the same), the room allocation is performed from the heat exchanger system with the smaller energy usage, so that Even in the number of rooms (cumulative number of rooms in charge), the total energy consumption can be minimized.

FIGS. 1A and 1B are diagrams schematically showing an example of a situation in which the basic mode of the room allocation support apparatus of the present invention is applied to room allocation of a hotel having a plurality of heat exchanger systems. FIG. 2 is a schematic configuration diagram of the entire system to which the basic mode of the room allocation support apparatus according to the present invention is applied. FIGS. 3A and 3B are diagrams showing an example of the database configuration of FIG. 2 in the case of the hotel configuration example shown in FIG. (C) is a graph of the table of (b) for easy understanding. FIGS. 4A and 4B are diagrams showing an example of the database configuration of FIG. 2 in the case of the hotel configuration example shown in FIG. (C) is a graph of the table of (b) for easy understanding. FIG. 5 is a diagram schematically showing an example of a heat exchanger system registration flow in the basic form of the room allocation support apparatus 1 shown in FIG. FIG. 6 is a diagram schematically showing an example of a room assignment support information determination flow in the basic form of the room assignment support apparatus shown in FIG. FIG. 7 is a diagram schematically showing an example of a hotel room configuration and a heat exchanger system configuration to which the general form of the room allocation support apparatus of the present invention is applied. FIG. 8 is a schematic configuration diagram of the entire system to which the general form of the room allocation support apparatus according to the present invention is applied. FIG. 9 is a diagram showing an example of a heat exchanger system registration table stored in the database by the processing of the heat exchanger system registration unit in FIG. FIG. 10 is a total amount table arbitrarily provided in association with the table of FIG. FIG. 11 is a diagram illustrating an example of a permutation table of the system operation order stored in the database 59 by the processing of the heat exchanger system permutation calculation unit in FIG. 8. FIG. 12 is a diagram showing an example of a system operation characteristic table for each system operation order stored in the database 59 by the processing of the system operation characteristic registration unit of FIG. FIGS. 13A and 13B are diagrams showing examples of the room allocation determination first table and the second table stored in the database by the processing of the hotel reservation information acquisition unit and the room allocation support information determination unit of FIG. is there. FIG. 14 is a diagram schematically showing an example of a heat exchanger system registration flow in the room assignment support apparatus shown in FIG. FIG. 15A is a diagram schematically showing an example of a room assignment support information determination flow in the room assignment support apparatus shown in FIG. FIG. 15B is a continuation of the flow of FIG. 15A. FIG. 16 is a diagram schematically illustrating a hotel configuration and a heat exchanger system configuration in the first example of the general form. FIG. 17A shows one of the system operation characteristic tables of FIG. 12 in the first example. (B) is a graph of (a). FIG. 18A shows another one of the system operation characteristic table of FIG. 12 in the first example. (B) is a graph of (a). FIG. 19A shows another one of the system operation characteristic table of FIG. 12 in the first example. (B) is a graph of (a). FIG. 20 is a diagram schematically illustrating a hotel configuration and a heat exchanger system configuration in the second example of the general form. FIG. 20A shows one of the system operation characteristic tables of FIG. 12 in the second example. (B) is a graph of (a). FIG. 21A shows another one of the system operation characteristic table of FIG. 12 in the second example. (B) is a graph of (a). FIG. 23A shows another one of the system operation characteristic table of FIG. 12 in the second example. (B) is a graph of (a). FIGS. 24 (a) and 24 (b) are diagrams showing the relationship between the conventional room allocation and the operation status of the heat exchanger system in a hotel equipped with a plurality of heat exchanger systems.

  Hereinafter, an embodiment of a room allocation support apparatus in a hotel or the like of the present invention will be described with reference to the drawings. A hotel will be described as a typical example of accommodation facilities such as hotels and inns.

(1) Basic Form of Room Allocation Support Device (1-1) Outline Prior to describing a specific configuration of a basic form of a room allocation support apparatus according to the present invention, an outline will be described.
FIGS. 1A and 1B are diagrams schematically showing an example in which the basic mode of the room allocation support apparatus of the present invention is applied to a room allocation of a hotel having a plurality of heat exchanger systems.

  The hotel room configuration and the heat exchanger system configuration in FIG. 1A are the same as those in the conventional example in FIG. The shaded area is the use room after the room assignment is executed. The used room rate (number of used rooms / total number of rooms) is 75%, the same as in FIG. In this case, room allocation is performed from a heat exchanger system having a large number of rooms per system (if the number of rooms is the same, it may be from either). As a result, all rooms from the 3rd floor to the 5th floor and 5 rooms on the 6th floor are allocated, and all the 7th floor rooms are vacant. Accordingly, the heat exchangers HP5, HP4, HP3, and HP2 can be operated (ON), while the heat exchanger HP1 can be stopped (OFF). The total energy consumption is 8kW / h, which is 80% of the maximum.

  In the hotel room configuration and heat exchanger system configuration in FIG. 1B, the number of rooms on each floor from the third floor to the seventh floor is the same in 12 rooms, and the total number of rooms is 60. Each floor is one heat exchanger system, and the heat exchangers on each floor from the third floor to the seventh floor are HP5 ′, HP4 ′, HP3 ′, HP2 ′ and HP1 ′. In this example, five heat exchanger systems are mixed with different energy consumption, HP5 ', HP4' and HP3 'are 2kw / h, HP2' and HP1 'are 4kW / h (these The numerical value of the amount of energy used is an example for explanation. The maximum energy consumption when all heat exchanger systems are operating is 14 kW / h. The shaded area is the use room after the room allocation is executed, and the use room rate is 75%. In this case, room allocation is performed from a heat exchanger system with a small energy usage amount per system (if the energy usage amount is the same, either may be used). As a result, all rooms from the 3rd floor to the 5th floor and 9 rooms on the 6th floor are allocated, and all the 7th floor rooms are vacant. Accordingly, the heat exchangers HP5 ′, HP4 ′, HP3 ′, and HP2 ′ can be operated (ON), while the heat exchanger HP1 ′ can be stopped (OFF). The total energy consumption is 10 kW / h, the maximum of 71%.

  In the example of FIG. 1 (a), room allocation is performed from a heat exchanger system having a large number of rooms per system, and in the example of FIG. 1 (b), a room from a heat exchanger system having a small energy consumption per system is used. Allocation is performed. In this way, it is preferable to determine the order of the heat exchanger system for performing room allocation in consideration of the number of rooms in charge per system or the amount of energy used.

  However, instead of allocating rooms in order of increasing number of rooms in each heat exchanger system or in ascending order of energy consumption, after allocating to all of the rooms in any one heat exchanger system, another arbitrary one Even if room assignment is performed by a method of starting assignment to the holding room of the heat exchanger system, energy saving can be realized as compared with the above-described conventional example of FIG. In the conventional example shown in FIG. 24, since assignment to a reception room of another heat exchanger system occurs before assignment to all the reception rooms of one heat exchanger system (that is, leaving an empty room), it is useless. The heat exchanger system will be operated. This is because in the conventional example, room allocation is performed without regard to the heat exchanger system. In the present invention, for example, in the example of FIG. 1B, even if room allocation is performed sequentially from the seventh floor downward, all the rooms on the third floor are vacant, so the heat exchanger HP5 ′ can be stopped. This is the most basic feature of the present invention.

  As shown in the examples of FIGS. 1A and 1B, all rooms on one floor do not have to be a single room for a single heat exchanger system, but a plurality of single rooms for a single heat exchanger system. The place may be arranged in any way in the hotel.

(1-2) Overall Configuration Diagram of Apparatus FIG. 2 is a schematic configuration diagram of the entire system to which the basic form of the room allocation support apparatus according to the present invention is applied.
The room allocation support device 1 operates in cooperation with the hotel reservation system 2 and the heat exchanger control system 3. For this purpose, it is assumed that they are connected by an appropriate communication means (LAN or the like).

  The hotel reservation system 2 is a well-known general system and has reservation information on the day when room allocation is performed. The reservation information includes at least the number of rooms required on the day (the number of reservation rooms). The room allocation support apparatus 1 acquires reservation information from the hotel reservation system 2 and provides room allocation support information to the hotel reservation system 2.

  The heat exchanger control system 3 is a known general system, and is a centralized management system that directly controls the operation and stop of each of a plurality of heat exchanger systems. The room allocation support device 1 provides the heat exchanger control system 3 with information on operation or stoppage for each heat exchanger system determined as a premise of the room allocation support information.

  The room allocation support apparatus 1 can be implemented as an appropriate computer system. The room allocation support processing unit 10 is a computer into which a program that realizes the functions of the apparatus is installed. The computer functions as the apparatus when the CPU reads the program into a memory and executes the process. The room allocation support processing unit 10 is connected to a management terminal 18 for allowing a user to check the processing status and the contents of the database 19 on a screen display and to make necessary inputs. The room allocation support processing unit 10 is connected to a database 19 for storing various related data.

  The room allocation support processing unit 10 is a processing unit in charge of each function, such as a heat exchanger system registration unit 12, a system operation characteristic registration unit 13, a hotel reservation information acquisition unit 14, a room allocation support information determination unit 15, and a room allocation support information transmission. Unit 16 and a heat exchanger operation stop instruction unit 17.

The heat exchanger system registration unit 12 registers in advance in the database 19 information related to each heat exchanger system, such as the number and location of rooms in each heat exchanger system, and the energy usage of each heat exchanger system.
The system operation characteristic registration unit 13 sequentially operates from the state where all the heat exchanger systems are stopped (all stopped states) to the state where all the heat exchanger systems are operated (all operating states), The number of rooms used from the fully stopped state to the fully operational state and information on changes in the accumulated energy usage amount are registered in the database 19 in advance.
The hotel reservation information acquisition unit 14 acquires reservation information from the hotel reservation system 2.
The room allocation support information determination unit 15 determines which heat exchanger system the assigned room is an assignable room based on the information stored in the database 19 and the reservation information. The determined information becomes room allocation support information.
The room allocation support information transmission unit 16 transmits the determined room allocation support information to the hotel reservation system 2.
The heat exchanger operation stop instruction unit 17 transmits to the heat exchanger control system 3 information on operation or stop for each heat exchanger system determined as the premise of the room allocation support information.

(1-3) Database Configuration FIGS. 3A and 3B are diagrams showing an example of the configuration of the database 19 in FIG. 2 in the case of the hotel configuration and the heat exchanger system configuration shown in FIG. . (C) is a graph of the table of (b) for easy understanding.

  FIG. 3A shows an example of the heat exchanger system registration table 301 stored in the database 19 by the processing of the heat exchanger system registration unit 12 of FIG. As data items, "system name (here, the name of the heat exchanger is used as the system name)" which is a name for identifying each heat exchanger system, "number of rooms handled" which is the number of rooms each heat exchanger system is responsible for, It has a “room location” indicating the location of the host room and an “energy consumption (kW / h)” of each heat exchanger system.

FIG. 3B shows an example of the system operation characteristic table 302 stored in the database 19 by the processing of the system operation characteristic registration unit 13 of FIG.
The “system operation order” of the heat exchanger system is stored in the first row. In the basic mode, this system operation order is determined in advance (for example, by user input).
The “number of used rooms” in the second row indicates the number of used rooms in which the number of rooms in use is accumulated when each heat exchanger system is sequentially operated from the fully stopped state to the fully operated state in accordance with this system operation order.
The “occupancy ratio (%)” and “vacancy ratio (%)” in the third and fourth lines are calculated from the ratio of the number of used rooms in the second line to the total number of rooms. The sum of “occupancy rate (%)” and “vacancy rate (%)” is 100%.
The “number of operating systems” and “number of stopping systems” on the 5th and 6th lines are the same as the number of systems to be operated when each heat exchanger system is operated sequentially from the fully stopped state to the fully operating state according to this system operation order. The number of lines. The sum of “the number of operating systems” and “the number of stopped systems” is always the total number of heat exchanger systems (here, 5 systems).
“Accumulated energy consumption (kW / h)” on line 7 is the energy used by each heat exchanger system when each heat exchanger system is operated sequentially from the fully stopped state to the fully operational state according to this system operation order. Is a cumulative value.

  FIG. 3C is a graph of the system operation characteristic table 302 of FIG. The horizontal axis is the occupancy rate (%). The left vertical axis is the number of operating systems of the heat exchanger, and the right vertical axis is the cumulative energy usage (kW / h). As an example, the case where the use room rate is 75% is indicated by a dotted line.

  FIGS. 4A, 4B, and 4C are the same as FIGS. 3A, 3B, and 3C, in the case of the hotel configuration and the heat exchanger system configuration shown in FIG. 1B. It is. FIG. 4A shows an example of the heat exchanger system registration table 401 stored in the database 19 by the processing of the heat exchanger system registration unit 12 of FIG. FIG. 4B shows an example of the system operation characteristic table 402 stored in the database 19 by the processing of the system operation characteristic registration unit 13 of FIG. FIG. 4C is a graph of the system operation characteristic table 402 of FIG.

(1-4) Processing Flow FIG. 5 is a diagram schematically showing an example of a heat exchanger system registration flow in the room allocation support apparatus 1 shown in FIG. Hereinafter, the case of the hotel configuration and the heat exchanger system configuration of FIG.

  This heat exchanger system registration flow is executed in advance prior to the room allocation support information determination flow. First, information on each of a plurality of heat exchanger systems in a hotel is input from the management terminal 18. The information includes at least the number and location of rooms handled by each heat exchanger system and the energy usage of each heat exchanger system (step S11).

  The input information of the heat exchanger system is registered in the heat exchanger system registration table 301 illustrated in FIG. 3A (step S12).

  Next, the system operation order of a plurality of heat exchanger systems is determined. For example, a screen for allowing the management terminal 18 to select a method for determining the system operation order is displayed (step S13). One of the options of the determination method is a method in which the user inputs the system operation order from the management terminal (step S14). When a user decides, it decides by other conditions, such as a place of a possession room and superiority. As another option, the system operation order is automatically determined so as to operate in order from the heat exchanger system having a large number of rooms (step S15). For a plurality of heat exchanger systems having the same number of rooms, the order may be arbitrarily determined, or the user may input from the management terminal based on other conditions. As yet another option, the system operation order is automatically determined so as to operate in order from the heat exchanger system with the smaller energy consumption (step S16). For a plurality of heat exchanger systems having the same energy consumption, the order may be arbitrarily determined, or the user may input from the management terminal 18 based on other conditions.

  Once the system operation order has been determined, the number of rooms used and the amount of energy used are accumulated when each heat exchanger system is operated sequentially according to the system operation order. The energy usage amount accumulation value is registered in the system operation characteristic table 302 of FIG. In addition, in the room allocation support apparatus 1 of the basic form, since the energy usage amount accumulated value is not used, registration is arbitrary.

  FIG. 6 is a diagram schematically showing an example of a room allocation support information determination flow in the room allocation support apparatus 1 shown in FIG. Hereinafter, the case of the hotel configuration and the heat exchanger system configuration of FIG.

  First, reservation information on a target day for room allocation is acquired from the hotel reservation system 2 (step S21). The reservation information includes at least the number of reserved rooms.

  Next, the number of used rooms corresponding to the number of reserved rooms is detected with reference to the system operating characteristic table of FIG. For example, referring to the system operation characteristic table of FIG. 3B, when the number of reserved rooms is 45, it falls within the range of the number of used rooms 41 to 50 in the fourth column. The number of rooms used is detected. In the state of the fourth row, the four heat exchanger systems of the heat exchangers HP5, HP4, HP3 and HP2 are operated, and one heat exchanger system of the heat exchanger HP1 is stopped.

  Then, the instruction information of the content which makes the four heat exchanger systems of heat exchanger HP5, HP4, HP3, and HP2 operate, and stops one heat exchanger system of heat exchanger HP1 is transmitted to the heat exchanger control system 3 (S23). ). The heat exchanger control system 3 controls the operation and stop of each heat exchanger system according to the instruction information.

  Further, the location of each room in each of the four heat exchanger systems of the heat exchangers HP5, HP4, HP3, and HP2, which are operating systems, is acquired from the heat exchanger system registration table 301 in FIG. Acquired room locations (for example, 3rd to 6th floors) are assignable room locations. The information on the location of the assignable room is room assignment support information. The determined room allocation support information is transmitted to the hotel reservation system (step S24). For example, when a guest checks in, the hotel reservation system assigns a room from among rooms that can be assigned room assignment support information.

(2) General form of room assignment support apparatus (2-1) Outline The basic form of the room assignment support apparatus described above can be further expanded to a general form. In the general form, it is assumed that each of the plurality of heat exchanger systems has various numbers of rooms and energy usage. For example, in addition to a heat exchanger system with a large number of rooms and a large amount of energy consumption and a heat exchanger system with a small number of rooms and a small amount of energy consumption, a heat exchanger with a large number of rooms and a small amount of energy consumption On the other hand, there may be cases where heat exchanger systems with a small number of rooms but large energy consumption are mixed. When a large number of various types of heat exchanger systems coexist, it becomes difficult to determine the order of system operation in consideration of energy saving. The general form of the present invention makes it possible to rationally determine room allocation support information in consideration of energy saving even in such a case.

  FIG. 7 is a diagram schematically showing an example of a hotel room configuration and a heat exchanger system configuration to which the general form of the room allocation support apparatus of the present invention is applied. The heat exchanger systems A1, A2, A3, A4, and A5 on each of the five floors including the top floor each have eight rooms and energy consumption of 2 kW / h, and constitute an A system group. The heat exchanger systems B1 and B2 on the lower two floors below each have 10 rooms and energy consumption of 2 kW / h, and constitute a B system group. The heat exchanger systems C1, C2 and C3 on each floor of the lower three floors each have 10 rooms and energy consumption of 4 kW / h, and constitute a C system group. The heat exchanger systems D1, D2, D3, D4, and D5 on each of the five floors below it have 14 rooms and energy consumption of 3 kW / h, and constitute a D system group. In addition, it is assumed that there are a plurality of layers (that is, a plurality of heat exchanger systems) below that.

  In the general form, first, among a plurality of heat exchanger systems provided in a hotel, a plurality of heat exchange systems are defined as one system group in which both the number of carrying rooms per system and the amount of energy used are the same. Or categorize into multiple system groups. In addition, each heat exchanger system belonging to one system group does not need to have a continuous hierarchy as in the example of FIG. 7, for example, even if each system hierarchy belonging to one system group is dotted. In addition, systems belonging to two system groups may be mixed in one layer.

(2-2) Overall Configuration Diagram of Apparatus FIG. 8 is a schematic configuration diagram of an entire system to which a general form of a room allocation support apparatus according to the present invention is applied.
The room allocation support apparatus 5 operates in cooperation with the hotel reservation system 2 and the heat exchanger control system 3 similar to the apparatus of the basic form of FIG.

  The room allocation support device 5 can be implemented as an appropriate computer system. The room allocation support processing unit 50 is a computer into which a program that realizes the functions of the apparatus is installed, and the CPU functions as the apparatus when the CPU reads the program into a memory and executes processing. The room allocation support processing unit 50 is connected to a management terminal 58 for the user to check the processing status and the contents of the database 59 on the screen display and make necessary inputs. The room allocation support processing unit 50 is connected to a database 59 for storing various related data.

  The room allocation support processing unit 50 is a processing unit in charge of each function, such as a heat exchanger system registration unit 51, a heat exchanger system permutation calculation unit 52, a system operation characteristic registration unit 53 for each system operation order of the heat exchanger system, and hotel reservation information. An acquisition unit 54, a room allocation support information determination unit 55, a room allocation support information transmission unit 56, and a heat exchanger operation stop instruction unit 57 are provided.

  The heat exchanger system registration unit 51 divides a plurality of heat exchanger systems into one or a plurality of system groups, and, for each system group, the number and location of the holding rooms of each heat exchanger system, and each heat exchanger system Information relating to each system group and each heat exchanger system, such as the amount of energy used, is registered in the database 59 in advance.

  The heat exchanger system permutation calculation unit 52 performs a process of obtaining all permutations of the system operation order until the plurality of heat exchanger systems are sequentially operated from all the stopped states to the full operation state. When obtaining this permutation, a plurality of heat exchanger systems included in one system group are treated as the same without being distinguished. This is a so-called “permutation including the same elements”.

  For each of the system operation orders calculated by the heat exchanger system permutation calculation unit 52, the system operation characteristic registration unit 53 includes the system operation order, the number of used rooms from the all-stop state to the all-operation state, and the accumulated energy usage amount. The change information is registered in the database 59 in advance.

  The hotel reservation information acquisition unit 54 acquires reservation information from the hotel reservation system 2.

  The room assignment support information determination unit 55 determines which heat exchanger system the assigned room is an assignable room based on the information stored in the database 59 and the reservation information. The determined information becomes room allocation support information.

  The room allocation support information transmission unit 56 transmits the determined room allocation support information to the hotel reservation system 2.

  The heat exchanger operation stop instruction unit 57 transmits to the heat exchanger control system 3 information on operation or stop for each heat exchanger system determined as the premise of the room allocation support information.

(2-3) Database Configuration FIGS. 9 to 13 are diagrams showing an example of the configuration of the database 59 in FIG. 8 in the hotel configuration and the heat exchanger system configuration in the general form shown in FIG.

  FIG. 9 is a diagram showing an example of the heat exchanger system registration table 901 stored in the database 59 by the processing of the heat exchanger system registration unit 51 in FIG. As data items, “system group name” that is a name for identifying each system group, “number of systems included in the system group” that is the number of heat exchanger systems included in the system group, and each heat included in the system group "Number of rooms in each system" that is the number of rooms in the exchange system, "Energy usage (kW / h)" that is the energy usage of each heat exchanger system included in the system group, included in the system group It has a “system name” for identifying each heat exchanger system and a “location room location for each system” indicating the location of the management room for each heat exchanger system.

  In the table of FIG. 9, the data AN, BN, CN, DN of the “number of systems included in the system group”, the data AR, BR, CR, DR of the “number of rooms in each system”, “energy usage ( “kW / h” data AW, BW, CW, and DW are variables, respectively, and actual values are actually stored.

  FIG. 10 is a total amount table 100 arbitrarily provided in association with the table of FIG. In the data item “total number of heat exchanger systems TN”, the total number of heat exchanger systems AN + BN + CN +. . . Is stored. The data item “total number of rooms TR” stores the total number AR × AN + BR × BN + CR × CN +... Of the number of rooms in the heat exchanger system. The data item “maximum energy usage TW” stores the maximum amount of energy usage (all operating states) AW × AN + BW × BN + CW × CN +.

FIG. 11 is a diagram illustrating an example of a permutation table 110 of the system operation order stored in the database 59 by the processing of the heat exchanger system permutation calculation unit 52 of FIG. Since the total number of heat exchanger systems is TN, the total number of normal permutations is _{TNP TN} . However, here, the heat exchanger system included in one system group is not distinguished. For example, A1,... An included in group A are treated as the same. Therefore, the total number of permutations of the heat exchanger system in this case is
_TN C _AN x _TN-AN C _BN x _TN-AN-BN C _CN x.
For example, when the total number TN of heat exchanger systems is 6 systems, the A group is 3 systems, the B group is 2 systems, and the C group is 1 system, the permutation of all the heat exchanger systems is ₆ C ₃ × ₃ C ₂ X ₁ C ₁ = 60. One permutation corresponds to one system operation order in which the heat exchanger system is sequentially operated from the fully stopped state to the fully operational state.

  The permutation table 110 in FIG. 11 selects, as data items, a “permutation number” for identifying each permutation, a “permutation (system operation order)” that is a specific array of permutations (system operation order), and the permutation as a comparison target. It has a “selection / non-selection flag” indicating whether or not to do so.

  In addition, since the heat exchanger system included in one system group is not distinguished as being the same, in FIG. 11, this is represented by “*” such as A * and B *. For example, A * means that any of A1 to An may be used. However, as a matter of course, there is no overlap (for example, two A1s) in one permutation.

  The “selection / non-selection flag” is arbitrarily provided. In permutation calculation, a very large number of permutations may be calculated. Accordingly, the calculated permutation may include a permutation that is never adopted due to various circumstances. For example, there is a situation in which a room assigned to a group B heat exchanger system is not preferentially assigned based on room conditions. In this case, the permutation having one or more B * s at the head is excluded from the comparison target by turning off the “selection / non-selection flag”.

  FIG. 12 is a diagram showing an example of the system operation characteristic table 120 for each system operation order stored in the database 59 by the processing of the system operation characteristic registration unit 53 of FIG. The system operation characteristic table 120 of FIG. 12 is basically created for all permutations (system operation order) included in the permutation table of FIG. It is not necessary to create the case where the “selection / non-selection flag” is turned off, but if the situation changes and the “selection / non-selection flag” is turned on, the system operation characteristic table 120 is created. .

In the first row, “system operation order” corresponding to one permutation in the permutation table 110 in FIG. 11 is stored.
The “number of used rooms” in the second row indicates the number of used rooms in which the number of rooms in use is accumulated when each heat exchanger system is sequentially operated from the fully stopped state to the fully operated state in accordance with this system operation order.
The “occupancy rate (%)” and “vacancy rate (%)” in the third and fourth lines are calculated from the number of used rooms and the total number of rooms in the second line.
The 5th and 6th lines are for the A group, the 7th and 8th lines are for the B group, and the 9th and 10th lines are for the C group. These numerical values are the number of systems to be operated in each system group and the number of systems to be stopped when each heat exchanger system is sequentially operated from the fully stopped state to the fully operated state in accordance with this system operation order. The sum of the “number of active systems” and the “number of stopped systems” of each system group is always the number of systems AN, BN, CN, etc. included in each system group.
“Cumulative energy consumption (kW / h)” on line 7 indicates the energy usage of each heat exchanger system when each heat exchanger system is operated sequentially from the fully stopped state to the fully operational state according to this system operation order. This is a cumulative value.

  13A and 13B are examples of the room allocation determination first table 130 and the second table 131 stored in the database 59 by the processing of the hotel reservation information acquisition unit 54 and the room allocation support information determination unit 55 of FIG. FIG.

  The room allocation determination first table 130 in FIG. 13A includes, as data items, “date” indicating the date on which room allocation is performed, “reserved room number” included in the reservation information acquired from the hotel reservation system, and reserved room number. Based on the “reserved room rate (%)” calculated from the total number of rooms, the specified room information included in the reservation information (if there is a specified room, the location of the room), and the specified room information The “designated room system” acquired from the heat exchanger system registration table 901 in FIG. 9, “the comparison target permutation number” extracted as the comparison target from the permutation number in which the selection / non-selection flag of the permutation table 110 in FIG. It has a “determined permutation number” indicating the permutation of the system operation order finally determined (described in FIGS. 15A and 15B below).

  In the “designated room information”, data such as “16th floor” indicating the location of the designated room is stored in addition to “designated room is present” when, for example, the reservation customer desires a specific room. Note that a designated room is not necessarily designated as a single room, and a specific hierarchy or a part thereof may be designated. When there is no designated room, data of “no designated room” is stored. When the designated room is designated, in “designated room system”, the heat exchanger system having the designated room as the host room is acquired from the heat exchanger system registration table 901 in FIG. 9 and stored.

  The room allocation determination second table 131 in FIG. 13B is created for each day of room allocation. The room allocation determination second table 131 is created after data is input to all the data items of the room allocation determination first table 130.

  The room allocation determination second table 131 includes, as data items, “system group name”, “number of stopped systems”, and “selected stopped system” that identify each system group. “Number of systems to be stopped” indicates the number of systems to be stopped in each system group in the number of used rooms corresponding to “number of reserved rooms” in the order of system operation specified by “determination permutation number” in the room allocation first table 130. Store. In that case, the system operation characteristic table of FIG. 12 is referred. Then, the number of systems corresponding to the “number of stopped systems” selected by the user from each system group is stored in the “selected stopped system” (described in FIGS. 15A and 15B below).

  Furthermore, the room allocation determination second table 131 includes “number of operating systems”, “selected operating system”, and “location of the holding room” as data items. The “operating system number” stores the number of operating systems of each system group acquired in the same manner as the above “stopping system number”. Then, the number of systems corresponding to the “number of operating systems” selected by the user from each system group is stored in the “selected operating system” (described in FIGS. 15A and 15B below). The “location of the guest room” is acquired from the heat exchanger system registration table 901 of FIG. 9 based on the “selected operating system” and stored.

(2-4) Processing Flow FIG. 14 is a diagram schematically showing an example of a heat exchanger system registration flow in the room allocation support apparatus 5 shown in FIG.

  This heat exchanger system registration flow is executed in advance prior to the room allocation support information determination flow. First, information on each of a plurality of heat exchanger systems in the hotel is input from the management terminal 58. The information includes at least the number and location of rooms handled by each heat exchanger system and the energy usage of each heat exchanger system (step S31).

  Based on the input information of the heat exchanger system, one or more systems having the same number of rooms and energy usage are classified as one system group into one or more system groups. Based on the division of each system group, it registers in the heat exchanger system registration table 901 illustrated in FIG. 9 (step S32).

  Next, the heat exchanger systems included in one system group are treated as the same, and the permutation of the system operation order of all the heat exchanger systems is obtained. All the obtained permutations are registered in the permutation table 110 of the system operation order in FIG. 11 (step S33).

  Subsequently, the permutation table 110 of the system operation order shown in FIG. 11 is displayed on the display screen of the management terminal 58, and the user is asked whether or not to select the system operation order to be compared (step S34). If the user does not select the grid operation order to be compared, all the selection / non-selection flags in the permutation table 110 in FIG. 11 are turned ON (step S35). That is, all system operation orders are to be compared. On the other hand, when the user selects the system operation order to be compared, the system operation order to be compared is selected on the display screen. For the selected system operation order, the selection / non-selection flag in the permutation table 110 in FIG. 11 is set to ON, and the others are set to OFF (step S36).

  Next, according to the system operation order, each heat exchanger system is operated sequentially from the total stop state to the full operation state, and the number of used rooms accumulated in each heat exchanger system and the number of used rooms of each heat exchanger system The accumulated energy use amount obtained by accumulating the energy use amount is registered in the system operation characteristic table 120 for each system operation order in FIG. 12 (step S37). Note that the room allocation support apparatus 5 in the general form uses the accumulated energy usage value, so registration is essential.

  15A and 15B are diagrams schematically illustrating an example of a room allocation support information determination flow in the room allocation support apparatus 5 illustrated in FIG.

  First, reservation information on a target day for room allocation is acquired from the hotel reservation system 2 (step S41). The reservation information includes at least the number of reserved rooms and may include designated room information. The acquired reservation information is stored in the room allocation determination first table of FIG.

  Next, it is determined whether or not the designated room information is included in the acquired reservation information (step S42). When there is a designated room, a system including the designated room as a host room is specified with reference to the heat exchanger system registration table 901 in FIG. Subsequently, referring to the permutation table 110 in FIG. 11, when the system operation order selection / non-selection flag starting from the system including the designated room as the host room is OFF, it is turned ON (step S43). ). In order to ensure, it is preferable to turn off the other system operation order. This is because a system including a designated room must be a room allocation target, and is therefore positioned as a system that is preferentially operated.

  Subsequently, the current permutation table 110 of FIG. 11 is displayed on the display screen of the management terminal 58 for confirmation (step S44). Then, the user is asked whether or not to change the selection of the system operation order to be compared (step S45). If the user wants to change the selection of the system operation order to be compared as necessary, the selection / non-selection flag of the permutation table 110 in FIG. 11 is changed (step S46).

  After that, all the permutation numbers of the system operation order in which the selection / non-selection flag of the permutation table 110 in FIG. 11 is ON are stored in “comparison target permutation number” in the room allocation determination first table 130 in FIG. . At this time, the data of data items other than “determination permutation number” is stored in the room allocation determination first table 130 of FIG.

  Next, all the system operation characteristic tables in the system operation order corresponding to the permutation numbers stored in the “comparison target permutation number” are extracted from the system operation characteristic table 120 in each system operation order in FIG. From the extracted system operation characteristic tables, the energy use amount cumulative value in the number of used rooms corresponding to the number of reserved rooms is acquired (step S47).

  The acquired energy usage cumulative values are compared, and one or a plurality of grid operation orders that are the minimum values are extracted and displayed on the display screen of the management terminal 58 (step S48).

  When a plurality of system operation orders are extracted, the user determines one system operation order to be employed in the room allocation from among them (step S49). This determination by the user is performed from a viewpoint other than energy saving, for example, the circumstances of the hotel, the room conditions, and the like.

  The number of operating systems and the number of stopped systems in each system group in the determined number of operating rooms in one system operation order are acquired from the system operation characteristic table 120, stored in the room allocation determination second table 131 in FIG. It is displayed on the terminal 58 (step S50). At this time, the systems included in each system group are also displayed. The user selects an operating system and a stopped system for each system group (step S51). For example, it is not necessary to select when all the systems in the system group are operated or stopped, but when a part is operated or stopped, it is necessary to select which system is operated or stopped. This determination by the user is performed from a viewpoint other than energy saving, for example, the circumstances of the hotel, the room conditions, and the like. Note that when a system to be operated in one system group is determined, a system to be automatically stopped is also determined. The reverse is also true. The operating system and the stopped system determined by the user are stored in the room allocation second table 131 of FIG.

  The information on the operating system and the stopped system determined as described above is transmitted as instruction information from the room allocation support device 5 to the heat exchanger control system 3 (step S52).

  In addition, based on the operating system and the stopping system determined as described above, the heat exchanger system registration table 901 in FIG. It transmits to the hotel reservation system 2 from the assistance apparatus 5 (step S53).

(2-5) General form example (1)
In order to make it easy to understand the general form of the room allocation support apparatus described above, several examples applied to a simple hotel configuration and heat exchanger system configuration will be shown.
16 to 19 relate to a general form example (1) to which the room allocation support apparatus 5 of FIG. 8 is applied.
FIG. 16 is a diagram schematically illustrating a hotel configuration and a heat exchanger system configuration in the general embodiment (1). The heat exchanger system of this example is divided into the following two system groups.
・ Group A (5 systems): 10 rooms per system
Energy consumption per system 2kW / h
-Group B (4 systems): 14 rooms per system
Energy consumption per system 2kW / h

  In the general form example (1), since the energy usage of all the systems is the same, room allocation can be performed according to the system operation order in which the system is operated from the system having a large number of rooms as in the basic form described above. From the viewpoint of energy saving, it is most advantageous. However, the most advantageous system operation order cannot always be adopted. For example, when there is a designated room. Therefore, the general form is applied.

FIG. 17A shows one of the system operation characteristic tables 120 of FIG. 12 in the general form example (1). (B) is a graph of (a).
This system operation order B *, B *, B *, B *, A *, A *, A *, A *, A * is the most advantageous system operation order in the first example. That is, in any number of used rooms, it is equivalent or advantageous (the accumulated energy usage amount is small) compared to other system operation orders.
Two examples of the relationship between the number of rooms used and the cumulative amount of energy used are as follows.
・ In the case of 25 rooms (24% use room rate): Cumulative energy consumption 4kW / h
・ In the case of 80 rooms (room ratio: 75%): Cumulative energy consumption 14kW / h

FIG. 18A shows another one of the system operation characteristic table 120 of FIG. 12 in the general form example (1). (B) is a graph of (a).
Two examples of the relationship between the number of rooms used and the cumulative amount of energy used are as follows.
・ In the case of 25 rooms (room rate 24%): cumulative energy consumption 6kW / h
・ In the case of 80 rooms (room ratio: 75%): Cumulative energy consumption 14kW / h

FIG. 19A shows another one of the system operation characteristic table 120 of FIG. 12 in the general form example (1). (B) is a graph of (a).
Two examples of the relationship between the number of rooms used and the cumulative amount of energy used are as follows.
・ In the case of 25 rooms (24% use room rate): Cumulative energy consumption 4kW / h
・ In the case of 80 rooms (room ratio 75%): cumulative energy consumption 16kW / h

  Comparing the energy usage amount cumulative value in each system operation order in FIGS. 17 to 19, the system operation order in FIG. 17 is the same or smaller than the other system operation order in any case. However, when the system operation order of FIG. 17 cannot be adopted due to various circumstances, a comparison is made in order to find the smallest energy usage amount accumulation value from other system operation orders. For example, a comparison will be made as to which of the grid operation orders in FIGS. 18 and 19 is energy saving. Then, when the number of used rooms is 25, the cumulative energy usage amount is smaller in the system operation order of FIG. 19, but when the number of used rooms is 80 rooms, the energy usage amount is higher in the system operation order of FIG. The cumulative value becomes smaller. Thus, it can be understood that the advantageous system operation order may be changed depending on the number of rooms used.

(2-6) General form example (2)
20 to 23 relate to a general form example (2) to which the room allocation support device 5 of FIG. 8 is applied.
FIG. 20 is a diagram schematically illustrating a hotel configuration and a heat exchanger system configuration in the general form example (2). The heat exchanger system of this example is divided into the following two system groups.
-Group C (5 systems): 10 rooms per system
Energy consumption per system 2kW / h
-Group D (4 systems): 10 rooms per system
Energy consumption per system 4kW / h

  In the general form example (2), since the number of rooms in all the systems is the same, it is possible to perform room allocation according to the system operation order in which the system is operated from the system with the smaller energy consumption as in the basic form described above. From the viewpoint of energy saving, it is most advantageous. However, the most advantageous system operation order cannot always be adopted. For example, when there is a designated room. Therefore, the general form is applied.

FIG. 21A shows one of the system operation characteristic tables 120 of FIG. 12 in the general form example (2). (B) is a graph of (a).
This system operation order C *, C *, C *, C *, C *, D *, D *, D *, D * is the most advantageous system operation order in the second example. That is, in any number of used rooms, it is equivalent or advantageous (the accumulated energy usage amount is small) compared to other system operation orders.
Two examples of the relationship between the number of rooms used and the cumulative amount of energy used are as follows.
・ In the case of 25 use rooms (use room rate 28%): Cumulative energy consumption 6kW / h
・ In the case of 68 rooms (room usage rate: 76%): Cumulative energy consumption 18kW / h

FIG. 22A shows another one of the system operation characteristic table 120 of FIG. 12 in the general form example (2). (B) is a graph of (a).
Two examples of the relationship between the number of rooms used and the cumulative amount of energy used are as follows.
・ In the case of 25 use rooms (use room rate 28%): Cumulative energy consumption 8kW / h
・ In the case of 68 used rooms (use room rate 76%): Cumulative energy consumption 22kW / h

FIG. 23A shows another one of the system operation characteristic table 120 of FIG. 12 in the second example. (B) is a graph of (a).
Two examples of the relationship between the number of rooms used and the cumulative amount of energy used are as follows.
・ In the case of 25 use rooms (use room rate 28%): Cumulative energy consumption 10kW / h
・ In the case of 68 rooms (room usage rate: 76%): Cumulative energy consumption 18kW / h

  Comparing the energy usage cumulative values in the order of operation of each system in FIGS. 21 to 23, the system usage order in FIG. 21 has the same or smaller energy usage amount cumulative value than the other system operation orders in any case. However, when the system operation order of FIG. 21 cannot be adopted due to various circumstances, a comparison is made in order to find the smallest energy usage amount accumulated value from other system operation orders. For example, a comparison will be made as to which of the grid operation orders in FIGS. 22 and 23 is energy saving. Then, when the number of used rooms is 25, the cumulative amount of energy used is smaller in the order of system operation in FIG. 22, but when the number of used rooms is 68, the order of energy usage in FIG. The cumulative value becomes smaller. Thus, the advantageous system operation order may be switched depending on the number of rooms used.

  As described above, by applying the general form of the present invention, it is possible to find the order of system operation that saves the most energy according to the number of rooms used (that is, the number of reserved rooms). By performing room assignment according to the found system operation order, energy saving can be realized.

1, 5 Room allocation support device 2 Hotel reservation system 3 Heat exchanger control system 10 Room allocation support processing unit 12 Heat exchanger system registration unit 13 System operation characteristic registration unit 14 Hotel reservation information acquisition unit 15 Room allocation support information determination unit 16 Room allocation Support information transmission unit 17 Heat exchanger operation stop instruction unit 18 Management terminal 19 Database 50 Room allocation support processing unit 51 Heat exchanger system registration unit 52 Heat exchanger system permutation calculation unit 53 System operation characteristic registration unit 54 Hotel reservation information acquisition unit 55 Room allocation Support information determination unit 56 Room allocation support information transmission unit 57 Heat exchanger operation stop instruction unit 58 Management terminal 59 Database

Claims (6)

A room allocation support apparatus for supporting room allocation in a hotel or the like having the plurality of heat exchanger systems, wherein each of the plurality of heat exchanger systems is in charge of one or a plurality of rooms and is controlled to be operated and stopped for each heat exchanger system. Because
(A) a heat exchanger system registration table in which each heat exchanger system is stored in advance in association with the number and location of the rooms in the heat exchanger system;
(B) by sequentially operating a plurality of full stop state of the heat exchanger system lines running order until the entire operating state and is determined in advance, when sequentially by running the heat exchanger system in accordance with the system operation sequence A system operation characteristic table in which the number of rooms used by accumulating the number of rooms in each heat exchanger system is stored in advance in association with the system operation order;
(C) means for acquiring the number of reserved rooms on the day of room allocation;
(D) The number of used rooms corresponding to the acquired number of reserved rooms is detected from the system operation characteristic table, and the heat exchanger system to be operated in the detected number of used rooms and the heat exchanger system to be stopped are based on the order of system operation. Means to decide
(E) a room allocation support for a hotel or the like, comprising: a unit that obtains the determined location of the assigned room of the heat exchanger system to be operated from the heat exchanger system registration table and determines the room as an assignable room apparatus. The energy consumption amount of each of the plurality of heat exchanger systems is the same, and when the number of each room is different, the system operation order is determined in descending order of the number of rooms. Item 10. A room allocation support apparatus for a hotel or the like according to Item 1. In the heat exchanger system registration table, each heat exchanger system and the energy usage amount of the heat exchanger system are further associated with each other and stored in advance.
2. The system operation order according to claim 1, wherein when the energy usage amount of each of the plurality of heat exchanger systems is different and the number of the respective rooms is the same, the system operation order is determined in ascending order of the energy usage amount. A room allocation support apparatus for a hotel or the like. Supports room allocation in hotels with multiple heat exchanger systems, where each of the multiple heat exchanger systems has a predetermined energy usage, is responsible for multiple rooms, and is controlled for operation and shutdown for each heat exchanger system A room allocation support device,
(A) Among the plurality of heat exchanger systems, those having the same number of rooms and the same amount of energy use are defined as one system group, and the plurality of heat exchange systems are divided into one or more system groups. A heat exchanger system registration table prestored in association with each heat exchanger system, the number and location of the rooms in the heat exchanger system, and the energy usage of the heat exchanger system;
The (b) all permutations strains operation order of up are sequentially operated from multiple full stop state of the heat exchanger system to a full operational state, dealing with heat exchanger system included in one of the family as the same For each of the determined system operation order, and the number of rooms used in accumulating the number of service rooms of each heat exchanger system when sequentially operating each heat exchanger system according to the system operation order, An energy usage accumulated value obtained by accumulating the energy usage of the heat exchanger system, and a system operation characteristic table for each system operation order stored in advance in association with the system operation order;
(C) means for acquiring reservation information including the number of reserved rooms on the day of room allocation;
(D1) means for detecting the number of used rooms corresponding to the acquired number of reserved rooms from all the system operation characteristic tables, respectively, and acquiring the accumulated energy usage amount in the detected number of used rooms;
(D2) by comparing the energy consumption cumulative value of the acquired system running each sequence, means for energy consumption accumulated value to extract one or more systems operating order is minimal,
(D3) in response to extracted the one or more from among the strains running order one system operation order is determined, the determined system operating order, the heat exchanger system and to run before Symbol used rooms Means for determining a heat exchanger system to be stopped based on the determined system operation order;
(E) a room allocation support for a hotel or the like, comprising: a unit that obtains the determined location of the assigned room of the heat exchanger system to be operated from the heat exchanger system registration table and determines the room as an assignable room apparatus. In the means of (d1), instead of detecting the corresponding number of used rooms from all the system operation characteristic tables, the corresponding number of used rooms is detected from the plurality of system operation characteristic tables selected as comparison targets, The room allocation support apparatus for a hotel or the like according to claim 4, wherein each of the accumulated energy usage values in the detected number of used rooms is acquired. In the means of (c), when the reservation information includes information on a designated room, the means further includes means for acquiring a heat exchanger system that is responsible for the designated room from the heat exchanger system registration table,
6. The room allocation support apparatus for a hotel or the like according to claim 5, wherein only the system operation characteristic table in the system operation order starting from the acquired heat exchanger system is selected as a comparison target.

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