RU107877U1 - INSTALLATION FOR AUTOMATIC TEMPERATURE CONTROL - Google Patents

Abstract

 Installation for automatic temperature control, comprising a housing of the installation in which a temperature controller, a furnace emulator, a fan and an element directing air flow from the fan to the furnace emulator are mounted, consisting of a transparent cover, a printed circuit board with a heater and a temperature meter and an oven emulator case installed on it with two slots with a width equal to the distance between the cover and the printed circuit board, and a length equal to the internal size of the length of the cover, characterized in that in the cover of the furnace emulator are made Slots and slots in the lid and body of the furnace emulator have movable frames, the length and width of which are equal to the length and width of the slots, and the internal dimensions of the frames are larger than the height of the furnace emulator.

Description

The utility model relates to installations for automatic temperature control in laboratory conditions, production and at home.

A device is known - the emulator of the furnace EP10 [1], which is used as a control object for the commissioning of installations operating with the use of temperature controllers. It is used in the organization of laboratory work in educational institutions, for the manufacture of various

experimental stands and demonstration layouts to test the operation of the control system without connecting to a real object. A built-in 10 W heater and a temperature meter (TCM 50M resistance temperature transducer), terminal sockets for connecting to a power supply network (220 V) and a temperature regulator, as well as an LED to indicate the flow of current through the heater (when heating is turned on) are mounted on the EP10 circuit board. The printed circuit board is mounted in a housing on which a transparent cover is sealed and fixed with screws, which allows you to see the emulator device, but at the same time prevents the possibility of penetration inside and getting burns or electric shocks. The printed circuit board is fixed in the housing due to its pressure on the housing cover. Therefore, the length of the printed circuit board is made greater than the length of the cover, which also allows the use of its terminal connectors without removing the cover. For ease of installation, the width of the printed circuit board is less than the width of the cover.

A drawback of the design of this emulator is the slow cooling of the heater after it is switched off naturally due to heat exchange with the environment. It cannot be used in modeling the processes of forced cooling of heated products, which is the case, for example, during hardening of steels. In addition, during laboratory work, time is spent cooling the heater to return to its original state, from which the use of the emulator for modeling by the next user begins.

A device is also known - a laboratory setup for studying a two-position temperature controller [2]. The installation uses a temperature regulator and an emulator of an EP10 furnace. An additional fan is installed on the transparent cover of the emulator, which creates an air flow. The air flow is in direct contact with the heater, which contributes to its rapid cooling after it is turned off. Heated air during fan operation is discharged from the heater through slots made in the cover.

The design flaw of this laboratory setup is the deterioration of the functionality of the transparent cover of the emulator of the furnace ЭП10. A fan installed on the front part of the transparent cover closes the emulator elements, which limits their visibility, and the presence of slots in the cover results in undesirable direct exposure of the air to the user during the experiments, the temperature of which is set depending on the parameters of the process under study, and not with the aim of creating comfortable conditions for his work.

The closest in technical essence and the achieved result is the installation for modeling automatic temperature control systems [3]. Two slots are made in the furnace emulator housing, which is part of the specified installation, with a width equal to the distance between the cover and the printed circuit board and a length equal to the internal size of the cover length, and an element is installed in the installation case that directs the air flow from the fan into one of the slots of the furnace emulator . This installation design allows you to effectively cool the heating element of the furnace emulator after it is turned off due to its direct contact with the air flow created by the fan, which enters the internal cavity of the emulator through one of the slots in its body without compromising the functionality of the structural elements of the furnace emulator. The transparent cover of the furnace emulator allows you to see the emulator device, but at the same time prevents the possibility of penetration into and getting a burn or electric shock. When conducting experiments, it prevents undesirable direct exposure to the user of air, the temperature of which is set depending on the parameters of the process being studied, and not with the aim of creating comfortable conditions for its operation. Hot air is discharged from the internal cavity of the emulator through a second slot in its body into the cavity formed by the body of the laboratory setup and its front panel.

The disadvantage of the design of this installation is its limited technological capabilities. It is used only for experimental work and cannot be used to control the microclimate of the user's working area after they are completed. This is due to the fact that the air flow with a controlled temperature can be discharged only into the internal cavity of the installation and therefore cannot be used to directly influence the user and create comfortable temperature conditions for him to work.

The problem solved by the utility model is to develop a plant design that can be used both for experiments on modeling automatic temperature control systems and for controlling the microclimate of the user's working area.

To solve this problem, an installation for automatic temperature control is used, which contains the installation housing, in which a temperature controller, a furnace emulator, a fan, and an element directing the air flow from the fan to the furnace emulator are mounted. The furnace emulator consists of a transparent cover, a printed circuit board with a heater and a temperature meter installed on it, and a furnace emulator body with two slots. The width of the slots is equal to the distance between the cover and the printed circuit board, and the length of the slots is equal to the internal dimension of the length of the cover. Slots are also made in the lid of the furnace emulator. Movable frames are installed in the slots of the cover and the body of the furnace emulator, the length and width of which are equal to the length and width of the slots in the body and the cover, and the internal dimensions of the frames are larger than the height of the furnace emulator.

This design of the installation allows it to be used both for experiments on modeling automatic temperature control systems and for controlling the microclimate of the user's working area by controlling the direction of the air flow at a given temperature by changing the position of the moving frames installed in the slots of the cover and emulator body. To control the microclimate of the user's working area, the frames are set to the position in which the slots of the cover and the emulator body are open. In this position, the air flow from the fan enters the interior of the emulator through the slots in its case, heats up with the heater turned on to the required temperature and is discharged into the user’s working area through the slots in its cover. With the heater turned off, the airflow has room temperature. To conduct experiments on modeling automatic temperature control systems, the frames are installed in a position in which the slots of the lid are closed and the slots of the body are open. In this position, the air flow from the fan through the element serving to direct it enters the interior of the emulator through one of the slots in its body and cools the heating element of the furnace emulator after it is turned off. Then, hot air is discharged from the internal cavity of the emulator through a second slot in its body into the internal cavity of the installation body. The transparent cover of the furnace emulator allows you to see the emulator device and the position of the frames, but at the same time prevents the possibility of getting inside and getting burned or electric shock and prevents the undesirable direct exposure to hot air on the user during the experiments.

Figure 1 shows a General view of the installation for automatic temperature control, figure 2 shows a section aa of figure 1 (an option to use the installation to control the microclimate of the working area of the user), figure 3 shows a section aa of figure 1 ( option to use the installation for experimental work).

The automatic temperature control installation comprises a housing 1, in which a temperature controller 2, an oven emulator 3, a fan 4 and an element 5 are mounted, directing the air flow from the fan 4 to the furnace emulator 3. The furnace emulator 3 consists of a transparent cover 6, a printed circuit board 7, s a heater 8 and a temperature meter 9 installed thereon, and a furnace emulator body 10. In the housing 10, two slots 11 are made, the width equal to the distance between the cover 6 and the printed circuit board 7 and the length equal to the internal size of the length of the cover 6. Slots 12 are made in the cover 6 of the furnace emulator 3. Movable slots 11 and 12 of the housing 10 and cover 6 are installed frames 13, the length and width of which is equal to the length and width of the slots 11 and 12, and the internal dimensions of the frames 13 are larger than the height of the emulator of the furnace 3.

Installations for automatic temperature control works as follows. The two-channel thermostat 2 installed in the installation case 1 includes a heater 8 installed on the circuit board 7 of the furnace emulator 3 or fan 4, depending on the temperature measured by the temperature meter 9. If the measured temperature is less than the set value, then heater 8 will automatically turn on. If the measured if the temperature is higher than the set value, fan 4 automatically turns on, the air flow from which is directed by element 5, depending on its position in slot 11 or into one of the holes her 11 body 10 of the furnace emulator 3. Through the slots 11, the air flow enters the internal cavity of the furnace emulator 3, formed by a transparent cover 6 and the housing 10. It cools the heater 8 and, depending on the position of the frames 13, goes through the second slot 11 into the interior of the housing 1 installation or through the slots 12 in the cover 6 is displayed in the working area of the user.

Experimental tests of the installation for automatic temperature control showed that it can be used both for experiments on modeling automatic temperature control systems and for controlling the microclimate of the user's working area.

Sources taken into account:

1. http://www.owen.ru/ Product catalog. Emulator furnace EP10. 2011 year

2. http://www.owen.ru/ Laboratory work “Study of the on-off temperature controller”. Tomsk Polytechnic University. 2010 year

3. The decision to grant a patent for a utility model dated March 14, 2011 by application No. 2011105802/12 (008227) dated February 16, 2011 “Installation for modeling automatic temperature control systems”.

Claims (1)

Installation for automatic temperature control, comprising an installation casing in which a temperature controller, a furnace emulator, a fan, and an element directing air flow from a fan to the furnace emulator are mounted, consisting of a transparent cover, a printed circuit board with a heater and a temperature meter, and a furnace emulator casing installed on it with two slots with a width equal to the distance between the cover and the printed circuit board, and a length equal to the internal size of the length of the cover, characterized in that in the cover of the furnace emulator are made Slots and slots in the lid and body of the furnace emulator have movable frames, the length and width of which are equal to the length and width of the slots, and the internal dimensions of the frames are larger than the height of the furnace emulator.