JPH0136024B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a multi-stage rotating body heat recording device with excellent heat-generating effect, which prevents heat conduction to the electric motor constituting the driving part and improves durability and safety. The present invention relates to a cooling mechanism in a rotating body heat recording device.

The present inventor published "Hot air method and apparatus" on July 13, 1981, "Hot air generation mechanism in hot air device" on July 14, 1981, and "Multistage rotating body heating system" on July 20, 1981. He proposed an invention related to a heat source that uses a series of rotating bodies in multiple stages, such as a "device".

In these inventions, when an electric motor is used as a rotating body, the electromagnetic mechanism of the electric motor may be adversely affected by the generated heat, resulting in problems such as a decrease in output and heat loss.

This invention was made based on the points mentioned above, and the electric motor of the rotating body is constantly cooled using air or other desired cooling medium, thereby preventing the adverse effects of heat caused by heat generation. It is an object of the present invention to provide a cooling mechanism in a multi-stage rotary body heat generating device that allows stable heat generating operation to be performed constantly at high output.

Embodiments of the present invention will be described below with reference to the drawings.

In each figure, 1 is a rotating body disposed in a cylindrical casing 2, and is composed of an electric motor 1a and a necessary number of rotating blades 1b. The configuration is,
Any number may be used as long as it is two or more.

3 indicates a frictional heat generating part formed in the rotation area R of the rotating blade 1b of each rotating body 1, and in the gap g formed between the rotary blade 1b and the cylindrical casing 2, a pressure equilibrium state of reduced pressure or increased pressure is generated. At the bottom, an effective frictional heat generation effect is exerted.

Reference numerals 4 and 5 denote a gas inlet port and a gas outlet port respectively connected to the gas introduction part 6 and the gas outlet part 7 of the cylindrical casing 2. is configured so that the amount of passing through is maintained at a value smaller than the suction and discharge capacity of each rotating body 1, thereby achieving a desired constant pressure equilibrium state of depressurization or pressurization in the cylindrical casing 2, improving heat generation efficiency. It is desirable to make it useful for In Fig. 1, the gas inlet 4 and the gas outlet 5 are shown as pipe structures equipped with valves as flow rate regulating mechanisms _V1 and _V2, respectively, but as shown in Fig. 3, the air direction can be freely changed. , and flow rate adjustment mechanisms such as dampers V ₁ , V ₂
A side ventilation configuration may also be used.

The embodiment shown in FIGS. 1 and 2 shows a configuration in which the rotating body 1 is vertically installed in a cylindrical casing 2, but in the embodiment shown in FIG. The electric motor 1a is oriented horizontally with respect to the shaped casing 2 and alternately in different directions.
shows a configuration in which the casing is housed in the cylindrical casing 2 and installed vertically, and the installation method may be any configuration as long as it is multi-stage.

8 is a shield that locally surrounds and shields only the electric motor 1a portion, 9 is a space thereof, 10 has one end opened in this space 9, and the other end is a cylindrical casing 2.
two or more suction tubes that are open to the outside; 11 is a discharge tube that has one end opened in the space 9 and the other end opened inside the cylindrical casing 2; 12 is a discharge tube that opens the electric motor 1a; Cylindrical casing 2 via shield 8
Shows a support plate that can be placed and fixed inside.

By the way, in the space part 9, a white-legged fan 13 is disposed as shown by the chain line in FIGS. Cooling can be performed by forced circulation, and although not shown, the discharge pipe 11 may be extended to the outside of the cylindrical casing 2 and led out to the outside of the cylindrical casing 2.

Further, the cooling medium sucked and discharged by the suction tube 10 and the discharge tube 11 can be air, of course, or any desired one such as Freon gas can be used.

The action will be explained based on the above structure.

The cylindrical casing 2 is rotated by adjusting the flow rate adjustment mechanisms V ₁ and V ₂ of the gas inlet 4 and/or the gas outlet 5 to limit the flow rate of the gas to be inhaled and the gas to be discharged. The inside is either depressurized or pressurized, and the state is a desired constant pressure state in which the pressure difference between the inside and outside is almost balanced. In this constant pressure equilibrium state, the air sucked into the cylindrical casing 2 is subjected to a frictional heat generating effect in the frictional heat generating section 3 formed by the gap g in the rotational region R of each rotating body 1.
The temperature is gradually increased. Then, the gas whose temperature has risen sufficiently is discharged to the outside from the gas discharge port 5.

By the way, the electric motor 1a of the rotating body 1 is provided with a shield 8 on its outer periphery via a space 9, and is provided with a suction pipe 10 and a discharge pipe 11, so that external cooling air is During operation of the motor 1a, it constantly flows into the space 9 to cool the electric motor 1a, so that the conduction of heat due to heat generation in the frictional heat generating section 3 can be completely blocked, and the electric motor 1a can be protected from heat.

In particular, when the inside of the cylindrical casing 2 is in a reduced pressure equilibrium state, the pressure inside the cylindrical casing 2 is lower than that inside the space 9, so the cooling that flows into the space 9 through the discharge pipe 11 The gas has the advantage that it can be drawn in and discharged into the cylindrical casing after an effective heat exchange operation.

Therefore, the cooling effect can be achieved by introducing outside air without taking any special measures.

According to this invention, the inconvenience of heat conduction to the electric motor in a multi-stage rotating body heat recording device with extremely high heat generation effect can be cooled by an extremely simple means of inflowing a cooling medium, resulting in improved durability and This has the effect of making it possible to perform stable heat generation operations.

[Brief explanation of drawings]

FIG. 1 is a longitudinal sectional side view showing an embodiment of a multi-stage rotating body heating device equipped with a cooling mechanism according to the present invention, FIG. 2 is a sectional view taken along the line -, and FIG. It is a diagram. DESCRIPTION OF SYMBOLS 1... Rotating body constituted by electric motor 1a and rotary blade 1b, 2... Cylindrical casing, 3
...Frictional heat generating part, 4... Gas inlet, 5... Gas outlet, 8... Shielding body, 9... Space part, 10...
... Suction tube, 11... Discharge tube, R... Rotation area, g... Gap.

Claims (1)

[Claims] 1. Two or more rotating bodies are arranged in a cylindrical casing having a gas inlet and a gas outlet, and a frictional heat generating part is formed in the rotation area of each rotating body with a gap therebetween. , a multi-stage rotating body heating device that generates heat in stages by maintaining the inhaled gas in a constant pressure equilibrium state of reduced pressure or increased pressure, in which a driving portion of the rotating body is supported by the cylindrical casing; Wrapped in a shield, an electric motor directly connected to the rotating body is fixed to the shield, and a space is provided around the outer periphery of the electric motor, and a cooling medium is introduced into the space from outside the cylindrical casing. A cooling mechanism designed to cool the electric motor. 2. The cooling medium is supplied through a suction tube with one end opened outside the cylindrical casing and the other end opened into the space of the shield, and one end opened into the space and the other end inside the cylindrical casing. 2. A cooling mechanism in a multi-stage rotating body heat generating device according to claim 1, wherein the cooling mechanism is configured to circulate through open discharge pipes.