SU1057709A2 - Heat signal generator - Google Patents

Abstract

GENERATOR OF THERMAL SIGNALS by author. St. No. 628352, characterized in that, in order to increase the sensitivity, a thermomagnetic plate has a cavity with two diametrically located holes, one of which is connected to the outlet channel of the body cavity via a flexible pipe, and the other is connected to a hole through in the area of the nozzle connected to the source of cold coolant. O) ate about with

Description

The invention relates to elements of heat automatics, and more specifically to devices used to build logic circuits on thermal elements used for automatic control of various technological parameters related to temperature (heat transfer system).

According to the main author. St. No. 628352 a heat signal generator is known, comprising a housing with nozzles connected to hot and cold heat transfer sources and an output channel; a temperature sensor with nozzle shutters is installed inside the body cavity; On both sides of which are placed the nozzle flaps associated with the thermomagnetic plate, and a permanent magnet is mounted on one of the ends of the housing against the thermomagnetic plate 1.

The disadvantage of this generator is that the cold coolant enters the generator chamber, which is a dead end, therefore contacting the thermomagnetic surface. plates cold layers of the coolant do not move relative to the latter. Thus, the cooling rate of a thermomagnetic plate to a temperature lower than the Curie point is determined only by convective heat transfer from its surface, which reduces the sensitivity of the generator.

The purpose of the invention is to increase the sensitivity of the generator.

The goal is achieved by the fact that in the generator of thermal signals in a thermomagnetic plate there is a cavity with two diametrically placed holes, one of which is connected to the output channel of the body cavity through a flexible pipe, and the other is connected to a hole in the nozzle area through a flexible pipe -connected to the source of cold coolant.

The drawing shows a heat signal generator, a cut.

The generator includes a housing 1, forming a cavity (chamber) 2, in which a thermomagitla plate 4 is fixed with the help of a clapping membrane 3. Thermomagnetic plaspia 4 has a cavity 5 with holes 6 n 7. Hole 6 is connected c) n. 2 by a flexible pipe 8 and a channel 9. The inlet 10 to the channel 9 is placed in the area of the nozzle 1 1 for connection with the source of hololisio Rhol heat carrier. This time Meiiun .iu input 10 provides the possibility of its 1, o; hmchryi valve 12, which provides ..; ii.T and overlapping nozzle 11.

The valve 12 is made of elastic material, mounted on a thermomagnetic plate 4 and has a central 13 and a peripheral 14 locking parts. The central locking part 13 of the shutter 12 communicates with the nozzle 11, and the peripheral locking part 14 interacts with the wall of the chamber 2, where the entrance 10 to the channel 9 is located.

The hole 7 of the cavity 5 is reported by a flexible pipe 15 with the output channel 16 of the chamber 2.

H5a of the thermomagnetic plate 4 is also fixed to the flap 17, which interacts with a nozzle 18 connected to a source of hot heat carrier Prop. A permanently fixed magnet 19 is fixed against the thermomagnetic plate 4 inside the chamber 2 on the case 1. The thermomagnetic plate 4 is spring loaded 20. The plate 4 and the permanent magnet 19 form a temperature-sensitive element.

The generator works as follows.

In the initial state, the thermomagnetic plate 4 is attracted to the magnet 19 and with a 11 ”cold signal closed. Through the hot signal nozzle 18, the tetragon carrier enters chamber 2. Due to the presence of jumpers inside cavity 5 and flat connection along the contour, the entire thermomagnetic plate 4 is heated,

 as a result, it loses its magnetic properties, since the bond between the intramolecular fields is disrupted. The attractiveness of plate 4 to magnet 19 weakens and under the action of the elastic forces of spring 20, plate 4 abruptly moves to another extreme position. Nozzle 18 closes and a cold signal nozzle 11 opens. Due to the fact that the peripheral shut-off part 14 of the shutter 12 is elastic, it is pressed against the wall of the chamber 2. At the initial moment, the central shut-off part 13 opens the nozzle 11 and the cold heat carrier first flows through the inlet 10, the channel 9 and the pipeline 8 into the cavity 5 and then the peripheral closure part 14 is separated from the chamber wall and filled with the latter (where the permanent magnet 19 is placed) with a cold carrier. Moving along the cavity 5 and in contact with the outer surface of the plate 4, the cold coolant coolly cools it, reducing the time to reach the temperature below the Curie point, at which plate 4 again has magnetic properties. Due to the occurrence of magnetic attraction forces, plate 4 is reset to its original state.

5 The valve 12 interrupts the entry of cold coolant into the chamber 2 and the cavity 5 of the thermomagnetic plate 4. Next, the cycle of the generator is repeated. Fixing a thermomagyte plate relative-provides for the generation of periodic

but nozzles in the extreme positions of real-high-frequency signals in the thermal form of a 3.me clapping membrane with temperature differences

Thus, the proposed generating company of what and cold coolant.

1057709d

Claims (1)

GENERATOR OF HEAT SIGNALS by ed. St. No. 628352, characterized in that, in order to increase the sensitivity, a cavity with two diametrically placed holes is made in the thermomagnetic plate, one of which is connected through a flexible pipe to the outlet channel of the housing cavity, and the other through a flexible pipe and channel connected to an opening located in zone of the nozzle connected to a source of cold coolant.