RU190487U1 - Coolant temperature controller - Google Patents

Abstract

The coolant temperature regulator relates to the field of technical physics, in particular, to systems for the regulation of non-electric quantities. The technical result of the utility model is to increase the speed and reliability of the regulator. To do this, in the coolant temperature regulator, comprising a housing, a partition with holes dividing the housing into two cavities, one of which is connected to the hot coolant supply channel, and the second to the cold coolant supply channel, while the control winding is connected to the body the power source through contact groups, the closing contacts of which are placed on a rod mounted perpendicular to the partition, while the partition with holes is made of wear-resistant material, and mechanically The eski is connected with permanent magnets attached to the rod by means of a lever, the magnetic field of which is connected to the control winding. 1 il.

Description

The utility model relates to the field of technical physics, in particular, to the control systems of non-electric quantities.

Known temperature controller coolant (AS USSR №275557, CL. G05D 23/08, 1970), comprising a housing, a bimetallic temperature-sensitive element, made in the form of a partition with holes, dividing the housing into two cavities, one of which is connected to the feed channel the hot coolant, and the other with the cold coolant feed channel.

The closest analogue of the proposed utility model is the coolant temperature controller (as. USSR No. 608131 G08 / 31, IPC G05D 23/08, 1978) comprising a case, a bimetallic temperature-sensitive element, made in the form of a partition with holes made of a magnetostrictive material that separates the case into two cavities, one of which is connected to the hot coolant supply channel, and the other to the cold coolant supply channel, and a control winding is placed on the case, connected to the power source through contact groups, the closing contacts of which are placed on the rod, installed perpendicular to the partition, and the output channels are made in the cavities.

The disadvantages of these regulators is the low speed and low reliability in operation.

From the analysis of the known technical solutions, it is revealed that a technical problem in this area is the need to expand the arsenal of technical means used to control non-electrical quantities.

The technical result of the utility model is to increase the speed and reliability of the regulator.

To solve this problem and achieve the specified technical result in the proposed coolant temperature controller, comprising a housing, a partition with openings dividing the housing into two cavities, one of which is connected to the channel for supplying hot heat carrier, and the second to the channel for supplying cold coolant, the housing has a control winding connected to a power source through contact groups, the closing contacts of which are placed on a rod mounted perpendicular to the partition, When apertured septum is made of wear-resistant material, and is mechanically connected with the rod fixed to the lever by permanent magnets, a magnetic field which is associated with the control winding.

The drawing schematically shows the proposed coolant temperature controller.

The regulator consists of a housing 1, partitions of wear-resistant material 2, dividing the housing into cavities 3 and 4, one of which is connected to the output channel 5 for the hot heat carrier, and the second with the output channel 6 for the cold heat carrier. The partition 1 is made of wear-resistant material, having bypass holes 7 is controlled by a rod 8, permanent 9 magnets are fixed on the rod with the lever 9, the field of which is in interaction with the control winding field 11 when the contacts 12 and 13 located on the rod 8 connected with a partition of wear-resistant material 2 and valves 14 and 15. The output channels 16 and 17 are made in the upper and lower parts of the cavities for cold and hot coolant. The control winding is connected to the source 18.

The device works as follows.

First, the hot coolant is supplied to the input channel 5. The membrane 2 is made of wear-resistant material, pulls the rod 8 with the valves 14 and 15 and contacts 12 and 13 fixed on it. Element 2 moves until valve 15 blocks channel 6 for supplying cold coolant and moves on until contact 13 does not closes.

At the same time, a current from the power source 18 appears in the control winding 11, creating a magnetic field inside the housing 1 and acting on the electromagnets 10, the latter begin to move under the action of the field, moving the associated element 2 towards the channel 5 with the hot coolant, at this moment the inlet of channel 6 is supplied with cold coolant, the process of generating impulses of cold and hot coolants begins. When the valve 14 moves, the channel with the hot coolant closes, the cold coolant supplied to the inlet of the channel 6 together with the action of the permanent magnet increases the deformation of the wear-resistant element 2. The process continues until contact 12 is closed. In this case, the current in the control winding 11 changes its the direction and accordingly changes the direction of the magnetic field to the opposite, acting on the permanent magnets connected by a mechanical lever 9 with the rod 8 and the wear-resistant element 2, force the rod to move to 8 and bend to the wear-resistant element in the opposite direction, opening access to the hot coolant through the channel 5 and closing the cold-coolant channel 6 with the valve 15.

Further work process is similar. In order to avoid the pressure difference in the chambers 3 and 4 in the wear-resistant partition 2 holes 7 are made.

Channels 16 and 17 in cavities 3 and 4 increase the speed and reliability of the device, since there is no transfer of cold and hot coolants through the wear-resistant partition. If it is necessary to use hot and cold heat carrier pulses in one channel, the output channels can be combined outside the device.

Compared with the prototype of the proposed device will significantly improve the performance and reliability of the coolant temperature controller.

Claims (1)

The coolant temperature regulator, comprising a housing, a partition wall with holes dividing the housing into two cavities, one of which is connected to the hot coolant supply channel, and the second to the cold coolant supply channel, while the control winding is placed on the housing connected to the power source contact groups, the closing contacts of which are placed on a rod installed perpendicular to the partition, characterized in that the partition with holes is made of wear-resistant material and mechanically The eski is connected with permanent magnets attached to the rod by means of a lever, the magnetic field of which is connected to the control winding.

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