NL2016260B1 - Device for optically measuring a parameter of the material of a substrate for a plant. - Google Patents

Abstract

A device for optically measuring a parameter of the material of a substrate for a plant comprises a measuring device comprising a housing with a hollow pin-shaped part that has an open first end and is adapted to be inserted into the substrate with the first end, and which pin-shaped part has a second end that is opposite the first end of the pin-shaped part. The measuring member further comprises a stop part which connects to the second end of the pin-shaped part and which is adapted to abut with an abutment side thereof directed towards the pin-shaped part against the top of the substrate into which the pin-shaped part is inserted. The device further comprises a first length of glass fiber which extends at least into the pin-shaped part and is rigidly connected thereto and of which a first end is located near the open first end of the pin-shaped part and which first end of the first length of glass fiber is provided with a coating that is sensitive to the physical quantity to be measured. The first length of fiber optic connects via the second end of the first length of fiber optic located opposite the first end to or can at least be optically connected to measuring means for measuring the parameter on the basis of light signals originating from the coating.

Description

Brief indication: Device for optically measuring a parameter of the material of a substrate for a plant

Description

The present invention relates to an apparatus for optically measuring a parameter of the material of a substrate for a plant. The relevant parameter can be, for example, the oxygen percentage or the acidity of the substrate. The material of the substrate can be, for example, glass wool or rock wool.

In the European patent application EP 1 700 520 A1 a device is described for measuring the oxygen content at a number of places in substrate material. This device uses a measuring device to which a number of sensors connect. The sensors are each designed as glass fiber lengths which are provided with a coating that is sensitive to oxygen at their free ends. The substrate lies in a trough-shaped holder on a plate. Standing pipes of different lengths are attached to the plate and protrude into the substrate. The glass fibers are inserted from the underside through the pipes into the substrate such that the respective coatings are located in the root region of plants growing in the substrate. It is a drawback of the known device that it is unsuitable for use on a larger scale and in an economically responsible manner in practice. The device described above appears to be intended for conducting scientific research. A further drawback of the device described is that there is a risk that the glass fibers are inserted into the substrate deeper or less deep than the length of the pipe through which a glass fiber runs. This entails the risk of incorrect measurements.

The invention now has for its object to offer at least an improvement for the above-mentioned problems. To this end, the optical measuring device according to the invention comprises a measuring member which comprises a housing with a hollow pin-shaped part that has an open first end and is adapted to be inserted with the first end into a substrate, and which pin-shaped part has a second end opposite to the first end of the pin-shaped part is located, the measuring member further comprising a stop part which connects to the second end of the pin-shaped part and which is adapted to abut against the upper side of the substrate with an abutment side thereof directed towards the pin-shaped part wherein the pin-shaped part is inserted, the device further comprising a first length of glass fiber which extends at least into the pin-shaped part and is rigidly connected thereto and of which a first end is located near the open first end of the pin-shaped part and which first end of the first length fiberglass has a coating that is sensitive to the te measuring physical quantity, wherein furthermore the first length of fiber optic via the second end of the first length of fiber optic located opposite the first end connects optically to or is at least optically connectable to measuring means for measuring the parameter on the basis of light signals reflected by the coating. The measuring means can thereby generate a light signal in the first length of glass fiber to the coating that reflects the light signal. The reflected light signal is received by the measuring means. The relevant parameter is determined on the basis of characteristics of the generated light signal and of the reflected light signal. Such a device is excellent for use from the top of a substrate, for example designed as a substrate mat. Furthermore, the use of the stop part in combination with the measure ensures that the first length of glass fiber is rigidly connected to the pin-shaped part, which connection, incidentally, does not necessarily have to be a direct connection between the first length of glass fiber and the pin-shaped part within the scope of the invention. relate to the fact that the depth with which the first length of glass fiber and thus the coating on the first end thereof can be accurately selected without the insertion of the first length of glass fiber into the substrate having to be done accurately. To this end, the invention offers the possibility of using measuring members with pin-shaped parts whose lengths differ.

To limit the cost price, it can be advantageous if the first length of fiberglass has no covering covering at least insofar as it extends into the pin-shaped part.

If the stop part is provided at least substantially concentrically with respect to the pin-shaped part, the ease with which a measuring member with the pin-shaped part thereof can be inserted into a substrate is improved and it is furthermore possible to cause the risk of skewed insertion into the substrate. pin-shaped part is reduced.

The ease of use can be further increased if the pin-shaped part is pointed at the first end and / or if the pin-shaped part has a conical longitudinal section.

According to a further possible embodiment of a device according to the invention, the second end of the first length is fiberglass located near the second end of the pin-shaped part or in the stop part, and the device further comprises a further measuring element with an engaging part which is adapted to be coupled to the stop part of the measuring member, as well as a second length of glass fiber which is connected to the engagement part and which has a first end which optically connects to the second end of the first length of glass fiber in the coupled state of the further measuring member with the measuring member, wherein the second end of the second length of fiber optics located opposite the first end of the second length of glass fiber optically connects or can at least be optically connectable to measuring means for measuring the parameter on the basis of light signals reflected by the coating. Such an embodiment provides the practical possibility of having a number of measuring members, which can be produced relatively inexpensively, (semi-) permanently put into one or a number of substrates, for example distributed over a department store, and at desired moments coupling these measuring members to a further measuring device for then measuring the desired parameter with the aid of the measuring means Within the scope of the possible embodiment discussed in the preceding paragraph, the invention also provides a further measuring device as such for use in a device according to the invention as discussed before and as will be discussed below.

If the engaging part has an endless edge within which the first end of the second length of glass fiber is located, a reliable and accurate coupling between the measuring member and the further measuring member can be realized with constructively simple measures. It may then be further advantageous from the point of view of striving for a stable coupling if the endless edge in the coupled condition surrounds the abutment part and connects thereto.

According to a further possible embodiment, the stop part comprises a chamber which is in communication with the cavity of the pin-shaped part and which chamber is in communication via a passage or can at least be in connection with the environment of the measuring device, wherein the second length of glass fiber is in coupled condition. of the further measuring device with the measuring device, extending through the passage. The use of a chamber offers in particular advantages in combination with closing means to be discussed in more detail which is offered within the chamber. A chamber can incidentally also be used if the first-length fiber optic connects optically to the measuring means directly, i.e. not via a second-length fiber optic. Such a permanent arrangement is particularly suitable for (semi-) continuous measurements in which, for example, a measurement is typically made every 4 minutes.

In order to be able to effect an optical connection of the second length of fiber optics to the first length of fiber optics in a simple manner, it is possible to choose to provide the passage provided in line with the first length of fiber optic.

By using closing means for closing the passage with the measuring element in the uncoupled state of the further measuring element and for closing the passage when the further measuring element is coupled to the measuring element so that the second length of glass fiber can pass through the passage extend, unnecessary exposure of the first length of glass fiber, in particular of the coating at the first end thereof, can be prevented or at least limited. Such exposure can, depending on the type of coating, lead to undesired degradation of the coating.

If the closing means comprise a resiliently flexible closing member which is connected to the stop member and is adapted to close the passage in the uncoupled state and to be bent away from the passage in the coupled state, the closing means and in general the measuring member can be carried out easily.

The closing means can be located in the chamber, whereby the chamber offers protection for the closing means.

The invention is further elucidated with reference to the following sketchy figures:

Figure 1 shows in vertical cross-section application of the invention with a culture block;

Figure 2 shows, in vertical cross-section, application of the invention to a substrate mat with the culture block according to Figure 1 thereon;

Figures 3a and 3b show a perspective view of a measuring device according to the invention, wherein the further measuring device is respectively not coupled and coupled to the measuring device of the measuring device;

Figures 4a and 4b show the measuring device according to Figures 3a and 3b in vertical cross-section.

Figure 1 shows a block-shaped culture block 1. The culture block 1 consists largely of substrate material 2, such as, for example, of glass wool or rock wool. At the bottom of the substrate material, a number of parallel grooves 3 are provided for draining off excess water. The culture block 1 further comprises a plastic film 4 which extends around and adjoins the substrate material 2. No plastic film is provided on the top and bottom of the culture block 1.

In the substrate material 2 grows a young plant 5 to be further cultivated, for example a tomato plant or a pepper plant. The roots of the plant 5 extend into the substrate material 2. To promote the growth of the plant 5, it is important to have insight into, among other things, the conditions that prevail in the substrate material. These conditions can be expressed, for example, in parameter values such as those of the acidity of the substrate material and those of the humidity of the substrate material. Depending on those values, adjustments can be made if desired, for example by supplying a certain amount of water to the substrate material 2 at certain times and by, for example, certain additional nutrients such as main elements nitrogen, phosphorus and potassium, macro elements calcium, magnesium and sulfur and trace elements iron, adding manganese, boron, copper, zinc and molybdenum to this water in a desired amount, composition and molecular form. To determine the above-mentioned parameters, a measuring member 6 is inserted into the substrate material 2 from the top. This measuring device 6 will be explained in more detail below with reference to the description of figures 3a to 4b. The term "measuring body" is not intended to express that the relevant body is independently capable of taking measurements. The term "measuring device" is only meant to indicate that the device in question is intended to be of service when taking measurements, for example of the pH value or the degree of humidity of the substrate material 2.

After plant 5 according to figure 1 has grown to a certain extent, in practice the cultivation block 1 with the plant 5 growing therein is placed on a beam-shaped substrate mat 11. The length of the substrate mat is such that two, three or more propagation blocks 1 can be placed thereon with some distance apart. The substrate mat 11 largely consists of substrate material 12, such as glass wool or rock wool. The substrate material is surrounded on all sides by a plastic film 14. Like film 4, the film 14 protects the substrate material against external influences, such as against germs that could disrupt the growth of plant 5 or such as against light to prevent algae growth in the substrate material. .. At the location of the culture blocks 1 that are placed on a substrate mat 11, openings are provided in the foil 14 so that the underside of substrate material 2 of the culture blocks 1 connects directly to the top of substrate material 12 of substrate mat 11. As clearly visible in Figure 2 the roots of plant 5 grow after cultivation block 1 has been placed on substrate mat 11 by substrate material 12 of substrate mat 11. Also for that further growth of plant 5 it is important to have insight into certain parameter values of substrate material 12. To gain insight obtainable in these values is a measuring device 6 in substrate material 12 by fol ie 14 put out.

Figures 3a to 4b show the measuring member 6 in combination with a further measuring member 16. The measuring member 6 is at least largely a plastic part which is manufactured by injection molding. The measuring member 6 has a housing which is formed with a hollow pin-shaped part 21 and a disc-shaped stop part 22. The measuring member further comprises a first length of uncoated glass fiber 23 which extends along the length thereof in the cavity of the pin-shaped part 21. Starting from the orientation according to figures 1 and 2, both the lower end 24 and the upper end 25 of the pin-shaped part 21 are open. The lower end 24 is free and pointed to facilitate insertion of the measuring device 6 into substrate material. For that reason, the pin-shaped part 21 also tapers down slightly. A coating 25 is provided at the lower end of the first length of glass fiber 23. The material of the coating 25 is sensitive to a physical or chemical quantity of the substrate material into which the measuring device 6 is inserted. The lower end of the first length of glass fiber 23, and thus the coating 25, when the measuring device 6 is inserted into substrate material, is in contact with that material and with the feed water present in the substrate material. The sensitivity of the coating 25 is reflected in the fact that the coating reflects light falling through the first length of glass fiber 23 onto the coating 25 such that with the aid of measuring means (not shown) on the basis of the difference between the characteristics of the incident light and the reflected light and the parameter value of the physical or chemical quantity to be measured can be determined.

The coating can be a hydrogel type, in other words the coating can be a hydrogel layer or comprise hydrogel. A hydrogel is a network of natural or synthetic polymer chains that are hydrophilic. A hydrogel has a strong absorbing capacity and contains water. Such hydrogel materials and coatings based on this are known to those skilled in the art and are not particularly limited to the present invention. In an aspect with a hydrogel coating, the hydrogel comprises one or more compounds (substances) that are sensitive to the parameter to be measured, such as the oxygen percentage or the pH value. As an example, compounds or combinations of compounds or chemical complexes can be mentioned which, upon contact with a specific compound to be measured (oxygen in the case of measuring the oxygen percentage), emit light rays which can be measured and which are a measure of the amount of the connection to be measured from which the value of the parameter can be determined.

The thickness of the coating is, for example, between 0.01 mm and 4.0 mm and in an embodiment between 0.03 mm and 1.00 mm. The thicker the coating, the longer it takes before, for example, oxygen from the environment has reached the connection sensitive to the parameter to be measured and thus a measurement can take place.

Examples of a coating that is suitable for measuring the oxygen percentage are described in the European publication EP 1 700 520 A1, inter alia in paragraphs [0009] and [0010] thereof, which paragraphs are to be regarded as inserted here. Further examples are given in international publication WO 01/63264 A1 of which at least pages 1, lines 4 to 24 are to be regarded as inserted here. Examples of a coating that is suitable for measuring a pH value are described in the American publication US 2005/0090014 A1, for example in the paragraphs [0033] to [0038] which paragraphs are also to be regarded as inserted here. .

The upper end 25 of the pin-shaped part 21 connects to the underside, hereinafter referred to as the abutment side 26, of the abutment part 22. In the bottom wall 28, the underside of which forms the abutment side 26, a central opening 27 is provided which is connected to the cavity of the pin-shaped part 21. The first length of glass fiber 23 is fixedly connected at its upper end to the bottom wall 28, for example by gluing in the central opening 27.

In addition to bottom wall 28, stop part 22 also comprises a cap part 29 with a circumferential wall 30 and an adjoining top wall 31. The bottom wall 28, the circumferential wall 30 and the top wall 31 define an internal chamber 32. A central passage 33 is provided in the top wall 31 which is in line with opening 27 and with the center line of the pin-shaped part 21. The passage 33 is closed in the condition according to Figure 4a by a leaf spring 34, for example of metal, provided in chamber 32 and with connection 35, for example a snap connection is connected to the bottom of the top wall 31.

The further measuring member 16 comprises a cover member 52 with an upper wall 53 and a circular wall 54 connecting to the bottom and outside thereof. The cover member 52 is made of aluminum.

The further measuring device 16 further comprises a second length of glass fiber 55 which, unlike the first length of glass fiber 23, does have a protective coating. A central passage 56 is provided in the upper wall 53 through which the second length of glass fiber 55 extends. The second length of glass fiber 55 is connected to the top wall 53, for example by gluing, such that the lower end of the second length of glass fiber 55 is still located just above the bottom of the revolving wall 54.

The inner diameter of the circumferential wall 54 is chosen to be slightly larger than the outer diameter of the circumferential wall 30 so that the further measuring element 16 can be slid tightly from the top over the stop part 22 until the bottom of top wall 53 rests against the top of top wall 31. During this movement, the lower end of the second length of glass fiber 55 projects through the passage 33 and thereby deforms leaf spring 34 elastically as indicated in Figure 4b. Said lower end of the second length of fiber optic 55 finally connects to the upper end of the first length of fiber optic 23. Thus, an optical connection is established between the two glass fibers 23 and 55.

The second length of fiber optic 55 is connected to (or at least can be connected to) optical measuring equipment connected to the end opposite the said lower end, which measuring device transmits a light signal from the latter end via successively the second fiber optic length 55, the connection between the second fiber optic length 55 and the the first length of fiber optic 23 and the first length of fiber optic 23 to the coating 25. Coating 25 will reflect this light signal in a manner that depends on the values of a physical or chemical quantity of the substrate material with which the coating 25 is in contact. The measuring equipment is able to determine the relevant parameter value on the basis of (the difference between the outgoing light signal and) the reflected light signal.

By using measuring members 6 and further measuring members 16, there is a very practical possibility of inserting a relatively large number of measuring members 6 distributed over various substrate materials, for example from growing blocks or substrate mats, into the substrate material permanently, at least during a growing period of a plant, in the substrate material to keep. Leaf spring 34 ensures that no light can reach coating 25 via passage 33. At set times, for example one or more times per day, it is then possible to make a round with the measuring equipment and a further measuring device 16 connected thereto along the various measuring devices 6 and for each measuring device 6 to make a measurement after temporary coupling of the further measuring device 16 with the relevant measuring device 6.

Claims (14)

An apparatus for optically measuring a parameter of the material of a substrate for a plant, comprising a measuring device comprising a housing with a hollow pin-shaped part that has an open first end and is adapted to be inserted into the substrate with the first end. and which pin-shaped part has a second end which is opposite the first end of the pin-shaped part, the measuring member further comprising a stop part which connects to the second end of the pin-shaped part and which is adapted to be connected to the pin-shaped part abut its directed abutment side against the top of the substrate into which the pin-shaped part is inserted, the device further comprising a first length of glass fiber which extends at least into the pin-shaped part and is rigidly connected thereto and of which a first end is situated near the open first end of the pin-shaped part and which first end of the first length of glass fiber is provided with a coating that is sensitive to the physical quantity to be measured, wherein furthermore the first length of fiber optic connects optically to or at least optically connectable to measuring means for measuring the parameter via the second end of the first length of fiber optic located opposite the first end on the basis of light signals reflected by the coating. Device as claimed in claim 1, wherein the first length of glass fiber has at least insofar as it extends in the pin-shaped part no covering. Device as claimed in claim 1 or 2, wherein the stop part is provided at least substantially concentrically with respect to the pin-shaped part. Device as claimed in any of the foregoing claims, wherein the pin-shaped part is pointed at the first end. Device as claimed in any of the foregoing claims, wherein the pin-shaped part has a conical longitudinal section. Device as claimed in any of the foregoing claims, wherein the second end of the first length of fiberglass is located near the second end of the pin-shaped part or in the stop part, and wherein the device further comprises a further measuring member with an engaging part which is adapted to to be coupled to the stop part of the measuring member, as well as a second length of glass fiber which is connected to the engagement part and which has a first end which optically connects to the second end of the first length of glass fiber in the coupled state of the further measuring member with the measuring member wherein the second end of the second length of fiber optics located opposite the first end of the second length of fiber optic connects optically or can at least be optically connectable to measuring means for measuring the parameter on the basis of light signals reflected by the coating. Device as claimed in claim 6, wherein the engaging part has an endless edge within which the first end of the second length of glass fiber is located. Device as claimed in claim 7, wherein the endless edge in the coupled state surrounds the abutment part and connects thereto. Device as claimed in any of the claims 6, 7 or 8, wherein the stop part comprises a chamber which is in communication with the cavity of the pin-shaped part and which chamber is connected via a passage or can at least be in connection with the surroundings of the measuring member the second length of glass fiber extending through the passage in the coupled state of the further measuring member with the measuring member. Device as claimed in claim 9, wherein the passage is provided in line with the first length of glass fiber. Device as claimed in claim 9 or 10, wherein the measuring element comprises closing means for closing the passage with the measuring element in the uncoupled state of the further measuring element and for not closing the passage with the measuring element in the coupled condition of the further measuring element with the measuring element so that the second length of glass fiber can extend through the passage. Device as claimed in claim 11, wherein the closing means comprise a resiliently flexible closing member which is connected to the stop part and is adapted to close off the passage in the uncoupled state and to be bent away from the passage in the coupled state. Device as claimed in claim 11 or 12, wherein the closing means are located in the chamber. Further measuring device for use in a device according to claim 6 or a claim dependent thereon.