JPH07265155A - Method for heating seat and device therefor - Google Patents

Abstract

PURPOSE:To surely heat respective seats while simplifying the wiring facility of heating at the observation seats of an institution. CONSTITUTION:This device is provided with plural sets of heater units 4, sensors 5 and controllers 8 parallelly connected to a power source circuit. The respective heater units 4 are individually mounted inside respective seats, and the sensor 5 detects the temperature raised by the heater unit 4 for each seat and outputs a temperature detect signal. The controller 8 inputs the temperature detect signal of the sensor 5, controls the exotherm of the heater unit 4 for each seat, controls the maximum temperature so as to be lower than a set temperature, individually heats the observation seats of the institution and individually executes heating for each seat.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seat heating method and apparatus for indoor and outdoor facilities having seats for viewing such as theaters, movie theaters, aquariums and stadiums.

[0002]

2. Description of the Related Art As a heating method for hundreds to thousands of seats in a theater or the like, a heating method by centralized control has been conventionally known. According to this method, as shown in FIG. 7, hundreds to thousands of seats are divided into several blocks (A, B, ...) And each block A, B ,. It manages the temperature of the seats.

FIG. 7 shows an example in which the temperature of the seats in each of the blocks A, B and C is managed in the central control room 22 for the blocks A, B and C including a plurality of seats. For example, in the block A, a plurality of seats A ₁ , A ₂ , ..., A
n, and each seat has a heater unit 2
1 is installed inside, and each heater unit 21 is connected to the central control room 2
Power source 23 in 2 is connected in parallel with power line 24,
Control of energization from the power source 23 to each heater unit 21 and control of the heat generation temperature of each heater unit 21 are performed in block A.
Is performed by the dedicated controller 25a. The temperature of the seat is detected by a sensor 26 installed in a specific seat of the seats A _{1 to} An included in the block A, for example, a bottom surface of the seat A ₁ , and a temperature detection signal of the sensor 26 is detected by a signal line 27. Is input to the controller 25a in the central control room 22 through. The controller 25a receives the temperature detection signal as input and performs power-on / off control or heat generation temperature control for each heater unit 21, and each seat in the block A is controlled to the same temperature. This is exactly the same for blocks B and C. Central control room 2
Dedicated controllers 25b and 25c for blocks B and C are also installed in the block 2.

[0004]

However, in the case of the heating method by the centralized control as described above, the power line is branched by the distribution board and the controller in the centralized control room and the wiring for each block are required. Furthermore, the wiring that connects the controller and the sensor must be laid for each block, and the wiring becomes enormous, which makes construction difficult in facilities where there are restrictions on wiring laying.

Another problem with the above method is that
The temperature of the seat is detected by a sensor installed in a specific seat among a plurality of seats included in one block. Therefore, when a person is seated in the seat in which the sensor is installed, The sensor operates by sensing the body temperature,
When the temperature exceeds a certain level, the heater unit is de-energized by a command from the controller, but even if a person sits in another seat in the same block, the temperature control is performed if the seat with the sensor is empty. There is a risk that seats within the same block will become unnecessarily hot and the seated person will suffer low-temperature burns if the function does not work. In addition, even if the seat with the sensor remains empty, the sensor senses heat when a load having a heat storage effect is placed on the seat, and when the temperature reaches a predetermined temperature, the sensor in the same block Even if the temperature of other seats is not supplied, the power supply to each heater unit is cut off, and the seat heating does not function.

In any case, in the temperature control for each block by the centralized control system, since the system is constructed on the assumption that the seats for the spectators will be full, there are variations in the use and diversity of use by an unspecified number of people. It has the drawback that it cannot handle all of the above. This is especially important when the heating of seats in the outdoor bleachers in cold regions does not work well depending on the seat usage.

It is an object of the present invention to provide a seat heating method and apparatus in which wiring facilities are simplified and the heating function of each seat is not affected by the seat usage.

[0008]

To achieve the above object, a seat heating method according to the present invention is a seat heating method for energizing a heater unit of a grandstand to generate heat. , Is installed for each seat, detects the temperature of each seat, controls the energization to the heater unit by the obtained temperature detection signal,
The heat generation temperature of the heater unit is managed individually for each seat.

Further, the heat generation temperature of the heater unit installed in each seat is individually controlled for each seat.

Further, the heating temperature of the seat is managed individually for each seat at each seat position.

In the seat heating apparatus according to the present invention,
A seat heating device for heating individual seats of a grandstand to heat each seat, including a plurality of sets of a heater unit, a sensor, and a controller, each set being connected to a power circuit. Connected in parallel, each heater unit is individually installed in each seat of the bleachers, receives heat from the power supply circuit to generate heat, and heats the seat at the heat generation temperature. The heating temperature of the heater unit is detected and the temperature detection signal is output to the controller. The controller receives the temperature detection signal of the sensor as input and controls the heating temperature of the heater unit for each seat to keep the heating temperature below the set temperature. Is limited to.

Each seat has a heater unit,
It has a sensor and a controller separately.

Further, each controller has a heat generation temperature control function of the heater unit, and the heat generation temperature control function of each controller is individually controlled by remote operation.

[0014]

[Function] As the seats of the bleachers, there are two independent chairs, and one that uses two or more seats like a bench or a chaise lounge. In the present invention, the seat includes both. When the seat is the seat of a single chair,
A heater unit is installed in the seat. When the seat surface has two or more seats, in principle, two or more heater units are installed in the seat surface, but the heater units may be installed over two or more seats.

The heater units installed in the front and rear seats of the bleachers are connected in parallel to the power circuit, and while the facility is being used, the heater units are energized to generate heat and are individually controlled by the controller provided in each seat. Temperature controlled.

The wiring equipment is only a power line connecting the power source and each heater unit, and the wiring equipment is simplified. Only the seat where the spectator is seated is detected by the sensor of the seated person's body temperature. When the temperature reaches the set temperature,
The controller acts to shut off the power to the heater unit and prevent the seat from overheating. The heating of each seat is completely unaffected by the conditions of the other seats. When remotely controlling the temperature of each seat, a separate signal line is laid, but the signal line may be wired in parallel to the controller of each heater unit by using the sequential calling method by the microcomputer operation, Alternatively, power line may be used for multiplex communication.

[0017]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a chair in the grandstand of the facility. The chair 1 has one seat as one seat.

FIG. 3 shows a chair 2 of a bench type, and the seating surface of the bench has a size of three seats in the embodiment. In FIG. 1, a seat plate 3 of a chair 1 shown in the embodiment is a hollow shell whose lower surface is opened as shown in FIG. 2, and internally has a heater unit 4, a sensor 5, and a heat insulating material 6 inside. The bottom opening is closed by the bottom plate 7. The heater unit 4 is a planar heating element or a linear heating element that heats the seating surface.

The sensor 5 is a thermistor, an electric thermocouple, a platinum resistor, or the like, and is installed on the seat surface side of the heater unit 4 corresponding to the central portion of the seat surface. The heat insulating material 6 prevents the heat of the heater unit 4 from being dissipated downward,
The heater unit 4 and the heat insulating material 6 are vertically stacked.
The chair 1 is further equipped with a controller 8 individually.

Although the controller 8 is installed in the seat plate 3 in the embodiment, the installation position of the controller 8 is not necessarily limited to the seat plate 3. It can be installed at an appropriate position on the chair, such as the seat plate 3 or the legs of the chair, or can be installed in the wiring box near the chair. When a thermistor is used as the sensor 5, the sensor 5 and the heater unit 4
FIG. 4 shows an example of wiring with

A contact 11 (falling contact) of the relay 9 is connected to the power supply circuit of the heater unit 4, and a comparator 10 is provided in the power supply circuit of the relay 9. The comparator 10 operates using the signal output of the sensor 5 and the temperature setting output of the variable resistor 13 as inputs. The diode 12 rectifies the alternating current of the power supply circuit to obtain direct current as the controller power supply.

The comparator 10 compares the output of the variable resistor 13 with the output of the sensor 5, outputs a relay drive signal when the sensor output exceeds the output of the variable resistor, and raises the relay 9. The power supply circuit of the heater unit 4 is shut off. The variable resistor 13 is a seated person (user).
Therefore, the controller is provided inside the controller so that it cannot be operated by itself and the administrator can perform variable operation.

FIG. 5 shows a wiring diagram of the heater unit of each seat. A row of chairs is arranged in the front and back and left and right in the bleachers of the facility.
, Are connected in parallel to the power source 18 through the power line 14, and while the facility is in use, the drop contacts 11 of the relay 9 energize the heater units 4, 4, ... The seats are heated.

When the heat generation temperature exceeds the set temperature, the relay 9 operates upon output of the temperature detection signal from the sensor 5, the contact 11 of the relay 9 is raised, and the energization of the heater unit 4 is stopped. When the seat is vacant, the temperature of the seat is determined solely by the outside air temperature, but in the seat where the spectator is seated, body temperature is added and heat is dissipated. As soon as it reaches the set temperature, the seat heating will be stopped.

Although the seat has been described with respect to the chair in FIG. 1, the same applies to the chair 2 in FIG. The chair 2 shown in FIG. 3 has three seats, and each seat is individually heated by a heater unit 4, and each heater unit 4 is individually temperature-controlled by a dedicated controller 8. .

FIG. 6 shows an example in which the set temperatures of the respective controllers 8 are centrally managed. In this embodiment,
The control signal wiring 17 is connected in parallel to each heater unit and led into the central control room 15, and the temperature setter 16 installed in the central control room 15 is computer-controlled to sequentially call each seat and the central control room. Communication is performed among the 15 units, and the set temperature of each heater unit is managed individually. It is also possible to control each controller through the power line 14.

[0027]

As described above, according to the present invention, the temperature of the heater unit for heating provided in each seat of the spectator seats of the facility is individually controlled, so that the spectators are different from those of the power control system. The heating function of the seat is not affected by the selection of seats on which seats are seated and the presence or absence of vacant seats, and the desired heating effect can be obtained individually for each seat. The heating temperature can be changed for each block or individually.

According to the present invention, basically, only a power line for supplying power to the heater block needs to be installed in the facility, wiring can be easily installed, and a signal for controlling the set temperature of the controller can be provided. When laying wiring, wiring for each block is not required unlike the power control method, and wiring can be installed in combination with the power line in parallel.

[Brief description of drawings]

FIG. 1 is a diagram showing an embodiment of a chair to which the device of the present invention is applied.

FIG. 2 is a sectional view of a seat plate of the chair shown in FIG.

FIG. 3 is a diagram showing another embodiment of the chair to which the present invention is applied.

FIG. 4 is a wiring diagram of a sensor and a heater unit.

FIG. 5 is a connection diagram showing an embodiment of the device of the present invention.

FIG. 6 is a connection diagram showing another embodiment of the device of the present invention.

FIG. 7 is a diagram showing a conventional example of a seat heating method.

[Explanation of symbols]

 1 chair 2 chair 3 seat plate 4 heater unit 5 sensor 6 heat insulating material 7 bottom plate 8 controller 9 relay 10 comparator 11 contacts 12 diode 13 variable resistor 14 power line 15 central control room 16 temperature setting device 17 signal wiring 18 power supply

Claims (6)

[Claims] 1. A method of heating a seat by energizing a heater unit of a grandstand seat to generate heat, wherein the heater unit is installed for each seat, and the temperature of the seat is detected for each seat, A heating method for a seat, characterized in that the energization of the heater unit is controlled by the obtained temperature detection signal to control the heat generation temperature of the heater unit for each seat individually. 2. The seat heating method according to claim 1, wherein the heat generation temperature of the heater unit installed in each seat is individually controlled for each seat. 3. The heating method for a seat according to claim 1, wherein the heating temperature of the seat is managed individually for each seat at each seat position. 4. A seat heating device for heating seats of a grandstand individually to heat each seat, which has a plurality of sets of a heater unit, a sensor, and a controller, and each set. Is connected in parallel to the power circuit, each heater unit is individually installed in each seat of the bleachers, receives heat from the power circuit to generate heat, and heats the seat at the heat generation temperature. The sensor detects the heat generation temperature of the heater unit for each seat and outputs a temperature detection signal, and the controller receives the temperature detection signal of the sensor as input and controls the heat generation temperature of the heater unit for each seat to generate heat. A seat heating device characterized in that the temperature is limited to a set temperature or lower. 5. The seat heating system according to claim 4, wherein each seat has a heater unit, a sensor, and a controller separately. 6. The controller according to claim 4, wherein each controller has a heating temperature control function of the heater unit, and the heating temperature control function of each controller is individually controlled by remote operation. Seat heating system described.