SU1075089A1 - Temperature indicator - Google Patents

Abstract

A TEMPERATURE SIGNALIZER containing a thermosensitive element made of a ferromagnetic material with a certain Curie point, a piston, a mouth (O c a c (D) new. In a guide cylinder, the end part of which is separated from the heat sensitive element by a heat insulating gasket, and a pressure transducer communicating with a cavity a cylinder, part of which is located on the same side of the barrel, filled with a gas or a mixture of gases under pressure, characterized in that, in order to increase the accuracy of temperature control, ochuvstvitelny element is in the form of a permanent magnet, and a part of the cylinder, located on the other side informing porschn and with a pressure transmitter, is filled with ferromagnetic fluid, wherein the cylinder wall and porschen made of nonmagnetic material.

Description

The invention relates to the control and measurement of temperature and can be used to visually and automatically signal that an object reaches a predetermined temperature under specific operating conditions (presence of electric fields, acoustic oscillations, vibrations, low light, high humidity) and control of the nature of the temperature rise process, mostly fast. A device for temperature control is known that contains a temperature-sensitive element made of a ferromagnetic material that changes magnetic properties when heated to a temperature corresponding to its Curie point 1. A temperature indicator device is known that includes a housing with a fixed permanent magnet fixed in it, a temperature-sensitive element made of a ferromagnetic material with a certain Curie point, thermal insulating elastic gasket, piezoelectric sensor 2. The disadvantage of these devices is the low reliability of signaling , especially when controlling the temperature of objects, access to which is difficult. The closest to the technical essence of the invention is a temperature detector containing a thermosensitive element made of ferromagnetic material with a certain Curie point, a piston mounted in a guide cylinder, the end part of which is separated from the thermosensitive element by a heat insulating pad and a pressure transducer communicating with the cylinder cavity , the part of which, located on one side of the piston, is filled with gas or a mixture of gases under pressure 3. However, when using This signaling device in the conditions of vibration can oscillate the piston with respect to the initial state, which reduces the control accuracy, especially in the p-process of temperature rise near the Curie point of the ferromagnetic material of the temperature-sensitive element, which determines the triggering level of the signaling device. The aim of the invention is to improve the accuracy of temperature control. The goal is achieved by the fact that in a temperature detector containing a thermosensitive element made of ferromagnetic material with a certain Curie point, a piston is installed in a guide cylinder, the end part of which is separated from the thermosensitive element by a heat insulating pad and a pressure transducer communicating with the cylinder cavity, part which is located on one side of the box, filled with a gas or a mixture of gases under pressure, the temperature-sensitive element is designed as a post This magnet, and part of the cylinder cavity, located on the other side of the core and in communication with the pressure transducer, is filled with ferromagnetic fluid, the cylinder walls and the piston being made of a nonmagnetic material. The drawing shows a diagram of the device. The detector contains a temperature-sensitive element 1 made of a ferromagnetic material with a Curie point corresponding to a controlled temperature, made in the form of a permanent magnet, a piston 2 installed in a guide cylinder 3, the end part of which is separated from the temperature-sensitive element by a sealed heat-insulating gasket 4, the pressure transmitter 5, communicating with the cavity of cylinder 3 through an opening 6 in its side wall. The piston 2 hermetically divides the cylinder cavity bounded by the inner surface of its walls and the heat insulating gasket 4 into two parts, the first of which, located on the side of the heat insulating gasket 4, is filled with ferromagnetic fluid (ferrofluid) 7, and the second gas or gas mixture 8, is under increased pressure. The detector works in the same way. In the initial position, when the value of the controlled temperature of the object T is less than the specified one (T-sv where is the Curie point of the ferromagnetic material) and the magnetic field created by the temperature-sensitive element 1 is maximum, the viscosity of the ferrofluid 7 under the influence of this floor is large monolith). The impact on the piston 2 with a mixture of 8 gases is balanced by the ferrofluid reaction 7. The external conditions, such as vibrations, accelerations, and moreover acoustic oscillations, electric fields, do not cause false alarms of the detector. When the object temperature increases and the magnetic field created by the thermosensitive element 1 decreases due to a decrease in the magnetization of the latter, the viscosity of the ferrofluid 7 decreases. The viscosity of the ferrofluid 7 decreases the piston 2 under the pressure of the gas mixture the inner surface of the cylinder 3), an increase in the pressure of the ferrofluid in the cavity of the cylinder and its extrusion through the opening b into the cavity of the pressure transducer 5. The volume of the ferrofluid 7 and the cross-section of the opening 6 are chosen such that during the use of the device

at temperatures close to the target (, (), the pressure transmitter 5 and the connecting pipe (not shown) did not completely fill the pressure transmitter 5 and the connecting pipe (not shown) with ferromagnetic fluid 7. For this reason, the use of this alarm device under conditions of a slow increase in the object temperature is not appropriate. corresponding to the Curie point of the temperature-sensitive element 1, the latter quickly loses its ferromagnetic properties and passes into the paramagnetic state, which is accompanied by are rapid disappearance of the magnetic field, a rapid decrease in the viscosity of the ferrofluid 7 until the viscosity of the colloidal solution. This leads to a sharp movement porschn 2, an abrupt increase in ferrofluid pressure

7 and the triggering of the measuring transducer 5, the output of which does not change with a further increase in temperature.

This alarm device also allows you to continuously monitor the process of increasing the temperature of the object from the beginning of the weakening of the magnetic field of the thermosensitive element 1 until the moment the alarm goes off. At the same time, according to the speed of movement of the piston 2 and the increase in pressure in the cavity of the measuring transducer 5, one can judge the heating characteristic of the control object, since the speed of movement of the piston depends on the viscosity of the ferrofluid, which in turn is determined by the temperature of the object being monitored.

Claims (1)

TEMPERATURE SIGNAL containing a thermosensitive element made of ferromagnetic material with a specific Curie point, a piston mounted. in a guide cylinder, the end part of which is separated from the thermally sensitive element by a heat insulating gasket, and a pressure transducer communicating with the cylinder cavity, a part of which, located on one side of the piston, is filled with gas or a mixture of gases under pressure, characterized in that, in order to increase accuracy temperature control, the heat-sensitive element is made in the form of a permanent magnet, and a part of the cylinder cavity located on the other side of the piston and in communication with the measuring transducer ovatelem pressure filled with ferromagnetic fluid, wherein the cylinder wall and piston are made of non-magnetic material. SU 1075