DE29709074U1 - Faucet controlled by infrared radiation - Google Patents

Description

Tung-Po TSAI, ₁₄₈₃₂

Taichung, Taiwan

Infrared ray controlled fitting

The present invention relates to an infrared ray controlled fitting having an electromagnetic valve.

Such valves are already known. They contain infrared ray sensors that actuate the electromagnetic valve. During operation, however, it can happen that the electromagnetic valve is not actuated due to a fault in the infrared ray sensor. Such a malfunction can lead to serious malfunctions.

The object of the present invention is therefore to provide an infrared ray-controlled fitting which contains a safety device which actuates the electromagnetic valve in the event of a malfunction of the infrared ray sensor.

This object is achieved by an infrared ray controlled fitting according to claim 1.

By replacing the conventional power source with a battery, this fitting has the advantage that it can be operated more independently of space.

In the following, the invention is described in more detail with reference to the accompanying figures.

Show it:

Fig. 1 is a perspective exploded view of an infrared-ray-controlled fitting in a preferred embodiment,

Fig. 2 is a schematic view of the infrared-controlled fitting in section, showing a magnetic tube in the raised position,

Fig. 3 is a schematic view of the infrared-controlled fitting in section, showing a magnetic tube in the lowered position and

Fig. 4 shows a cross-sectional view of an infrared-ray-controlled fitting as a structural unit.

Figures 1 to 4 show an infrared ray-controlled fitting which has a fitting body 50. In the fitting body 50 there is an electromagnetic valve 20 on which a lower plate 24 is arranged. Between the lower plate 24 and an upper plate 23 there is a solenoid 22 which is surrounded by a cylindrical hollow body 25. On the upper plate 23 there is a magnetostrictive switch 40 on which a battery 21 is mounted. An upper cover 54 covers the fitting body 50. An infrared ray sensor 30 is connected to the battery 21 via a lead wire.

The infrared ray-controlled fitting 30 has an integrated circuit 31. An infrared ray receiver 32, an infrared ray emitter 33 and a light-emitting diode 34 are mounted on the integrated circuit 31.

The electromagnetic valve 20 has an inner seat 266, a washer 2660 located in an upper cavity of the inner seat 266, a sleeve 26 disposed on the uppermost part of the inner seat 266, a hollow sleeve 267 located in the lower inner region of the inner seat 266, an annular body under the hollow sleeve 267, and a funnel-shaped tube 268 disposed between the hollow sleeve 267 and the annular body 269. A ring 2692 is located under the annular body 269. A through hole 2661 and an inlet hole 2662 are formed in the inner seat 266. The hollow sleeve 267 has a flow nozzle 2671. An outlet hole 2681 is formed in the funnel-shaped tube 268. A vent hole 2691 is formed on the annular body 269. A flow channel 2693 is formed on the ring 2692. The sleeve 26 has a disk 260. A pole 2631 is located in the upper portion of the sleeve 26. A cylindrical rod 263, a magnetic hollow cylinder 261, a spring 265, a plug 264 and a rubber pad 2642 are arranged in this order in the sleeve. A magnet 262 is located in the magnetic hollow cylinder 261. The plug 264 has a flange 2641.

The upper plate 23 has a central hole 231. The lower plate 24 also has a central hole 241. The sleeve 26 extends through the central hole 241 of the lower plate 24, the solenoid 22 and the central hole 231 in the upper plate 23. The pole 2631 is in contact with the magnetistrictive switch 40.

The fitting body 50 has a hollow interior 53, a water inlet 51, a water outlet 52 and a fastening element 56.

In Fig. 2, the magnetic hollow cylinder 261 is raised. During normal operation of the electromagnetic valve 20, the magnetostrictive switch 20 does not function. If a fault occurs, the magnetostrictive switch 40 sends a signal to the electromagnetic valve 20 so that the electromagnetic valve 20 operates normally again and the magnetic hollow cylinder 261 is raised.

In Fig. 3, the magnetic hollow cylinder 261 is lowered. In normal operation of the electromagnetic valve 20, the magnetostrictive switch 40 does not function here either. If a fault occurs, the magnetostrictive switch 40 sends a signal to the electromagnetic valve 20 so that the electromagnetic valve 20 works normally and in this case the magnetic hollow cylinder 261 is lowered.

Claims (2)

Protection claims 1. Infrared ray controlled fitting, comprising a fitting body (50), an electromagnetic valve (20) located in the fitting body (50), a lower plate (24) arranged on the electromagnetic valve (20), an upper plate (23), a solenoid (22) arranged between the lower plate (24) and the upper plate (23), a cylindrical hollow body (25) enclosing the solenoid (22), and an upper cover covering the fitting body (50), marked by a magnetostrictive switch (40) arranged on the upper plate (23), a battery (21) arranged on the magnetostrictive switch (40), an infrared ray sensor (30) which is connected to the battery (21) via a lead wire and an integrated circuit (31) on which an infrared ray receiver (32), an infrared ray emitter (33) and a light-emitting diode (34) are arranged, wherein the electromagnetic valve (20) comprises an inner seat (266), a washer (2660) located in an upper cavity of the inner seat (266), a sleeve (26) arranged on the uppermost part of the inner seat (266), a hollow sleeve (267) located in the lower inner region of the inner seat (266), an annular body (269) located under the hollow sleeve (267), a funnel-shaped tube (268) arranged between the hollow sleeve (267) and the annular body (269), a ring (2692) arranged under the annular body (269), a through hole (2661) and an inlet hole (2662), both formed in the inner seat (266), a flow nozzle (2671) arranged on the hollow sleeve (267), an outlet opening (2691) formed in the funnel-shaped tube (268), a ventilation opening (2691) formed on the annular body (269), and a fiow channel (2693) formed on the ring (2692), wherein the sleeve (26) comprises a disk (260), a pole (2631) arranged in an upper region of the sleeve (26), a cylindrical rod (263), a magnetic hollow cylinder (261), a spring (265), a plug (264) and a rubber pad (2642) arranged in this order in the sleeve, and a magnet (262) located in the magnetic hollow cylinder (261), wherein the plug (264) has a flange (2641), the upper plate (23) has a central hole (231),
the lower plate (24) has a central hole (241), the sleeve (26) extends through the central hole (241) of the lower plate (24), the solenoid (22) and the central hole (231) of the upper plate, and the pole (2631) is in contact with the magnetostrictive switch (40). 2. Infrared ray controlled axmatur according to claim 1, characterized in that the fitting body (50) has a hollow interior (53), a water inlet (51) and a water outlet (52).