DE102006052892A1 - Turbidity sensor for e.g. washing machine, has radiation transmitter and radiation receiver that are accommodated in housing sections, and glaring unit provided in one of housing sections and designed for minimizing scattered light - Google Patents

Abstract

The sensor (2) has a radiation transmitter (4) and a radiation receiver (6) that are arranged in a carrier e.g. printed circuit board, in such a manner that an optical path for measuring turbidity of fluid in the optical path is formed between the transmitter and the receiver. The transmitter and the receiver are accommodated in housing sections (10, 12), and a glaring unit (16) is provided in one of the housing sections and designed for minimizing scattered light, where the housing sections and the glaring unit are designed as a single piece.

Description

The The invention relates to a turbidity sensor according to the preamble of claim 1

Known Turbidity sensors, those in water-bearing Household appliances, such as. dishwashers or washing machines, are used as a radiation sensor serving diode and, for example, serving as a radiation receiver Phototransistor. The radiation transmitter and the radiation receiver are arranged on the legs of a substantially U-shaped carrier, so they have a radiation input to measure the turbidity of a form in the beam path located liquid. To the radiation sensor and the radiation receiver from the liquid shield, are the carrier housed in a housing with the radiation transmitter and the radiation receiver, that for the wavelength emulated by the radiation transmitter is permeable. This allows one one-piece Training the housing and thus a cost-effective Production.

The problem, however, that used as a radiation emitters diodes generate a conical light beam can lie in the edges of the housing. Reflections can cause unwanted stray light at the edges that negatively influences the measuring accuracy. To exclude the scattered light from disturbing edges of the housing, the housing of the turbidity sensor must be sized accordingly large. This in turn increases the space requirement in a water-conducting household appliance such as a dishwasher or a washing machine. To minimize the disturbing stray light or to turn it off, it is out of the DE 196 11 402 A1 known to produce housing of a milky transparent material having through portions of reduced wall thickness passage areas for a radiation transmitter and a radiation receiver, which then together form a beam path for measuring the turbidity of a liquid located in the beam path.

From the DE 103 58 647 A1 a sensor for transmission measurement is known, which has a diaphragm device, which is arranged on the carrier spaced from the sensor and / or the receiver and causes a reduction of the scattered light. The diaphragm device is designed as a separate component that takes up considerable space in the interior of the housing.

It It is therefore an object of the invention to provide a turbidity sensor, the reduced space requirement increased accuracy by reducing the interference caused by Has stray light.

The The object of the invention is achieved through a turbidity sensor with the features of claim 1.

there has the turbidity sensor, in particular for the installation in a water-conducting household appliance such as a dishwasher or a washing machine is formed, at least one radiation transmitter and a radiation receiver. The radiation transmitter and the radiation receiver are in such a way to each other arranged that they form a beam path through which in the water-bearing household appliance be carried out water can order by weakening the radiation imitated by the radiation emitter by means of the with the radiation receiver received signal the turbidity the liquid to determine. The radiation transmitter and the radiation receiver are in housing sections taken, which are housing sections of a one-piece Housing or alternatively to a housing from several housing sections can act. At least according to the invention in a housing section provided an aperture element that is designed for straylight minimization is. Thus, in a simple way, the proportion of interfering stray light reduces and thus a reduction in the dimension of the turbidity sensor possible.

Further is preferably provided that at least one lens element in Radiation direction in the area behind the radiation emitter and further preferably an aperture element arranged in the radiation direction in the area in front of the radiation receiver is. It is prevented by the lens element that of the radiation emitters imitated radiation forms conically and the aperture element becomes the influence of disturbing stray light reduced to the measurement result.

In a preferred embodiment is provided that the housing sections and the aperture element in one piece are formed. It can the housing sections and the diaphragm element, for example, made of a transparent plastic, for example by injection molding, e.g. using a 2K tool, be prepared. This allows a simple production and cost-effective installation.

It is preferably provided that the diaphragm element are formed substantially by weakening material. This makes it possible to produce the housing with the housing sections in one piece from a material, wherein only the material weakenings pass through areas for the radiation emitted by the radiation transmitter and the radiation received by the radiation receiver form. The other areas of the housing with the housing sections, however, can be made thicker by the wall thickness, so that the greater wall thickness in the remaining areas of influence of disturbing scattered light is reduced to the measurement accuracy.

In an alternative embodiment In contrast, it is provided that the housing sections at least one Has recess in which the diaphragm elements is inserted. This allows the housing with the housing sections and manufacture the visor element from different materials, the shutter element being e.g. is sprayed with plastic compound. In this case, the housing with the housing sections from one for the radiation emitted by the radiation emitter impermeable material be made.

Of the Radiation transmitter and the radiation receiver of the turbidity sensor can one support element each arranged, for example, as designed for SMD technology Boards are formed. Preferably, however, it is provided that both the radiation transmitter and the radiation receiver a carrier are arranged. Thus, the radiation transmitter and the radiation receiver defined Positions, which simplifies installation and subsequent adjustment the radiation transmitter and radiation receiver superfluous. Of course you can the carrier also as for the Be formed SMD technology designed board.

When Radiation transmitter and radiation receiver can all be in the desired Wellenlängenbereicht imitative or radiation-receiving components are used, such as. Laser diodes. Preferably, however, it is provided that the Radiation sensor at least one LED and the radiation receiver at least a phototransistor, a photodiode or a solar cell, so that the turbidity sensor from simple and inexpensive components is formed.

Further belongs to the invention a water-leading household appliance with at least one turbidity sensor. Furthermore belongs also to the invention, a housing for one Turbidity sensor according to the invention.

in the Below, the invention will be explained with reference to an embodiment.

It demonstrate:

1 a schematic sectional view of the radiation sensor according to the invention, and

2 a section of an alternative embodiment of a test sensor according to the invention.

It will be on the 1 and 2 Referenced.

The turbidity sensor 2 is on a carrier 22 built, which is a suitable for the SMD technology board. The carrier 22 has a U-shaped form, wherein at the two leg ends as a radiation transmitter 4 serving LED and serving as a phototransistor radiation receiver 6 are arranged opposite one another, so that between the radiation transmitter 4 and the radiation receiver 6 a ray path 8th is formed, in which after installation of the turbidity sensor 2 In a water-bearing household appliance water can enter and the turbidity in the beam path 8th located liquid can be determined.

The carrier 22 with the radiation transmitter 4 and the radiation receiver 6 is in a housing 24 taken in one piece from one essentially for the radiation transmitter 4 emitted radiation is made of permeable plastic material. The plastic material is chosen such that it is permanently resistant to corrosion in chemicals used in water-conducting household appliances such as dishwashers or washing machines. The housing 24 also has two in the region of the legs of the U-shaped carrier 22 lying housing sections 10 . 12 on which is a lens element 14 and an aperture elements 16 exhibit. Here is the lens element 14 in the radiation direction behind the radiation transmitter 4 arranged while the aperture element 16 in the direction of radiation in front of the radiation receiver 6 is arranged. The Elements 14 . 16 cause in particular that the radiating cone of the radiation transmitter shown by line elements 4 is minimized (cf. 2 ). The housing 22 Aside from the areas of the elements 14 . 16 a material in a wall thickness, resulting in a significant attenuation of the radiation from the transmitter 4 imitated radiation leads, so that are reduced by structurally caused measurement errors.

It is now up 2 Referenced.

In an alternative embodiment of the invention it is provided that the housing 24 in the area of the housing sections 10 . 12 recesses 18 . 20 in which a lens element 14 and an aperture elements 16 are used. Here are the elements 14 . 16 made of a material transmissive to the radiation emit- ted by the radiation emitter, while the housing 24 with the housing sections 10 . 12 from one for the of the radiation transmitter 4 Imitated radiation impermeable material is made. Manufacturing can be done using a 2K tool or prefabricated elements 14 . 16 For example, they are overmoulded with a suitable plastic compound.

The Elements 14 . 16 cause thereby that there is no conical propagation of the radiation from the transmitter 4 Imitating radiation comes, but that of the radiation transmitter 4 Imitated radiation substantially on the front of the radiation receiver 6 arranged aperture element is focused. It is according to in the embodiment 2

2

turbidity sensor

4

radiation sensor

6

radiation receiver

8th

beam path

10

housing section

12

housing section

14

lens element

16

diaphragm element

18

recess

20

recess

22

carrier

24

casing

Claims (10)

Turbidity sensor ( 2 ), in particular designed for installation in a water-conducting domestic appliance such as a dishwasher or a washing machine, at least comprising: - a radiation transmitter ( 4 ), and - a radiation receiver ( 6 ) which are arranged in such a way that they form a beam path ( 8th ) for measuring the turbidity of a in the beam path ( 8th ) and the radiation transmitter ( 4 ) and the radiation receiver ( 6 ) in housing sections ( 10 . 12 ), characterized in that at least in one housing section ( 10 . 12 ) an aperture element ( 16 ) is provided that is designed for stray light minimization. Turbidity sensor ( 2 ) according to claim 1, characterized in that at least one first lens element ( 14 ) in the radiation direction in the area behind the radiation transmitter ( 4 ) is arranged. Turbidity sensor ( 2 ) according to claim 1 or 2, characterized in that the aperture element ( 16 ) in the radiation direction in the region in front of the radiation receiver ( 6 ) is arranged. Turbidity sensor ( 2 ) according to one of the preceding claims, characterized in that the housing sections ( 10 . 12 ) and the aperture elements ( 14 . 16 ) are integrally formed. Turbidity sensor ( 2 ) according to one of the preceding claims, characterized in that the diaphragm element ( 16 ) are formed essentially by material weakening. Turbidity sensor ( 2 ) according to one of the preceding claims, characterized in that at least one housing section ( 12 ) a recess ( 20 ), in which the diaphragm element ( 16 ) is used. Turbidity sensor ( 2 ) according to one of the preceding claims, characterized in that the radiation transmitter ( 4 ) and the radiation receiver ( 6 ) on a support ( 22 ) are arranged. Turbidity sensor ( 2 ) according to one of the preceding claims, characterized in that the radiation transmitter ( 4 ) at least one LED and the radiation receiver ( 6 ) comprise at least one phototransistor, a photodiode or a solar cell. Water-conducting household appliance with at least one turbidity sensor ( 2 ) according to one of the preceding claims 1 to 8. Casing ( 24 ) for a turbidity sensor ( 2 ) according to one of the preceding claims 1 to 8.