DE2012547A1 - Device for the automatic lowering of the night temperature of radiators - Google Patents

Description

Device for the automatic lowering of the night temperature of radiators.

The invention relates to a device for automatic reduction the night temperature of radiators fitted with thermostatic valves.

In a known remote control with which the radiator valves can be controlled from a control center, the control takes place with electrical Elements.

Therefore it is necessary between the head office and the individual Arrange radiator valves electrical lines.

The aim of the invention is in such a remote control without the electrical lines between the control center and radiator valves.

To solve this problem, a device is provided according to the invention, the holdings in the im Radiator existing water one causes considerable pressure change, with each radiator valve being a throttle element contains, which when a pressure pulse occurs from a rest position to a Working position in which the flow cross-section of the valve is reduced, movable is.

When the heating element valve is at a temperature corresponding to the daytime Is in the normal position, the throttle element assumes its rest position. Through the When the pressure pulse is transmitted through the radiator water, the throttle element passes into the working position in which it reduces the flow area of the valve.

In this way, less water flows through the body, so that also less heat is transferred. When back from the night temperature to the day temperature is to be switched, a similar pressure pulse is transmitted, which then the throttle element moves into the rest position, so that the flow area of the valve receives the normal value again.

Such a device does not require electrical wiring and also no additional pipelines between the control center and the individual Radiator valves. Only a minor one is required to carry out the invention Modification of radiator valves, so that the switching device is considerably cheaper than the previously known and used devices.

In the case of central heating systems with a circulation pump, you can change the pressure cause quietly in the radiator water in a particularly simple manner by according to the invention with respect to the circulation pump beyond the intermediate radiators nearby of the furnace provides an additional shut-off valve. Is the circulation pump in the feed line, place the shut-off valve in the return line. By Closing the shut-off valve results in a considerable increase in pressure in the radiator water When the circulation pump is in the return, the shut-off valve is placed in the feed line.

When the shut-off valve is closed, water is produced in the radiator a slightly lower pressure reduction.

According to the invention, fully automatic operation can be achieved by that a solenoid valve is used as a shut-off valve, which is controlled by a timer is operated. The timer is preferably set so that the solenoid valve is closed for a time of 2 to 3 minutes, so that even in large heating systems the change in pressure lasts long enough to take effect at all points, so that all radiator valves in the The new switching status is reached The timer should normally generate two pulses within 24 hours.

In the case of the usual thermostatic radiator valves with a Bellows, the valve body is significantly impaired when the pressure in the radiator increases water considerably enlarged0 This adjustment of the valve body can be used, to cause a switchover of the throttle element by the invention Throttle element housed axially displaceable in the valve body of the radiator valve is and is mounted so that it is against the action of a return spring in a locked working position can be moved when the valve body moved up. A deregulation from the job can then be done by a subsequent upward movement of the valve body will be caused, in the last mentioned The case, the return spring pushes the throttle element back into the rest position, The The locking device can be designed in exactly the same way as the holding device of ballpoint pens with an axially movable push buttonO Up This results in a simple and reliable construction that is very can be manufactured inexpensively.

Further details and features of the invention emerge from the following detailed description and the accompanying drawing9 in one preferred embodiment of the invention is illustrated, for example, in The drawings show: FIG. 1 a schematic circuit diagram of a central heating system with an automatic remote control according to the invention and FIG. 2 shows a longitudinal section by a thermostatic radiator valve for the remote control according to the invention Fig.1 shows a heating furnace 1 with a feed line 2, which is located in the vicinity of the furnace 1 contains a circulating hull 3. The reflux line 4 to the furnace 1 contains a magnetic Operable shut-off valve 5, which can be operated by a timer 6. The timer is set so that it activates the solenoid valve 5 in the morning when from Night temperature is to be switched to day temperature for a period of 3 Minutes and then opens again. The timer also closes 6 the shut-off valve 5 in the evening when switched from day temperature to night temperature should be for 3 minutes.

When the solenoid valve 5 is closed, the water pressure increases in the radiator considerably, since the circulation pump 3 continues to run. This pressure increase will used to switch over the radiator valves in the manner to be described below.

The thermostatic irritant valve of Figure 2 has a conventional valve seat 7 and a valve body 8, the axial displacement of which by a bellows 9 in such a way happens that the valve closes more and more as the room temperature rises will.

Inside the valve body 8 there is an axially movable one Drossstlelement 19, whose conical tip on the lower end face of the valve body 8 protrudes, the throttle element can counter the influence of a compression spring 10 from the valve body 8 are pushed out.

The throttle element 19 is pushed out with a pressure piston 11, which comes to rest on the upper end of the throttle element 19. The piston 11 is axially displaceable and is in contact with the throttle element by a compression spring 13 held. Between the piston 11 and an Ittilse 12 in which the piston is axially displaceable is, there is a known per se in the drawing 4> he is not shown in detail Locking device.

This locking device keeps the piston 11 behind one certain downward movement in a manner known per se in a position in which the throttle element 19 to a considerable extent, opposite the end face of the valve body 8 is advanced, Fig.2 shows the throttle element 19 in the retracted Rest position. When the piston 11 of the locking device one more time is depressed, there is an unlocking, so that an advanced throttle element 19 is returned to the rest position shown in FIG can be. This position of the throttle element can be adjusted with the adjusting screw 14 set, the lower end of which comes to rest on the top of the piston 11, The hole for the adjusting screw 14 is opposite the space outside the bellows 9 shut off airtight with an additional bellows 15.

If the pressure of the water in the radiator is explained with reference to Fig Way is increased by closing the solenoid valve 5, the valve body moves 8 a little upwards, oo that the bellows 9 is stretched.

As a result, the piston 11 and the throttle element 1, 9 move opposite one another the valve body 8 downwards, so that the throttle element in the protruding position arrives in which it with the help of the lock between the piston 11 and the sleeve 2 is held. If the solenoid valve 5 opens again three minutes later, normalized himself too the water pressure in the radiator again, so that the valve body 8 returned to the position that is determined by the bellows 90 Now but the throttle element 19 is so far advanced relative to the valve body 8 that the bore in the valve seat 7 is given a considerably reduced cross-sectional area.

In this way, only a smaller amount of water can now pass through flow through the radiator, so that the heat generation is reduced.

hen the solenoid valve 5 closes again briefly the next morning, the valve body 8 is again opposite the throttle element 19 and the piston 11 pushed up, ao that the lock between the piston 11 and the Sleeve 12 releases. After this release of the locking, the spring 10 of the throttle element 19 back to the rest position of Fig. 2: Lengths of the Uhermostat ^ RadiatorXtentil then works in the usual way during the daytime until the timer 6 again the solenoid valve 5 briefly closes in the evening.

Claims (1)

P a t e n t a n s p r ü c h e. 1. Device for the automatic reduction of the night temperature of radiators provided with thermostatic valves, characterized by means (5, 6) for the short-term generation of a considerable change in water pressure in the radiators and further characterized by throttling elements disposed on each radiator valve (99), which when pressure pulses occur between an ineffective rest position and move to a working position in which the flow cross-section of the valve is reduced. 2. Device according to claim 1 for central heating with a circulation pump, characterized in that in the radiator feed circuit Beyond the circulating pump (3) an additional shut-off valve <r) is provided near the furnace (1), 30 Device according to claim 2, characterized in that the shut-off valve (5) is a solenoid valve that can be operated with a timer (6). 4. Apparatus according to claim 1, characterized in that the valve body (8) of the Heizkdrperventiles provided with an axially displaceable throttle element (19) is that against the action of a return spring (10) in a locked working position is advanced when the valve body (8) moves upwards9 and that at a subsequent upward movement of the valve body (8) is unlocked0