RU73091U1 - LENS MODULE - Google Patents

Abstract

The lens module includes a housing attached to the circuit board and provided with bottom receiving holes for accommodating LEDs or sensors mounted on the circuit board and a flange with an orienting groove, a lens element inserted into the flange and fixed with an orienting groove to correctly install the specified lens element and a cover worn on the housing to prevent the lens element from falling out and provided with through holes for accommodating convex portions of the lens element therein. In this case, the lens element has flat protrusions entering the corresponding through holes in the housing coaxially with the LEDs or sensors.

Description

1. The scope of the invention:

The present invention relates to lens modules, in particular, a lens module for use in a banknote receiver for determining the authenticity of banknotes, the lens module being provided with several types of mounting elements that provide a specific and accurate location of the lens element between the housing and the lid.

2. Description of analogues:

Following the rapid development of technology, our lifestyle has changed. Everywhere, various vending machines are used (dispensing machines, vending machines for selling tickets, vending machines for exchanging money, etc.) for selling various products without the participation of the seller. These vending machines do a lot of work and create convenience for people. Money changers are usually equipped with a coin acceptor and a banknote receiver.

Nevertheless, both sellers and consumers are always concerned about the problem of counterfeiting money, especially paper currency. Following the development of computer technology, attackers can use a computer to scan, copy, and print paper money. As a result, paper money is provided with funds that make it difficult to counterfeit. Visual means that make paper money counterfeiting difficult include paper material, color, signs, tags, etc., which are easy to see with the naked eye. However, verification of invisible funds that impede counterfeiting requires special machines or tools to establish the authenticity of the banknote. A well-known identifier intended for these purposes is based on the use of paper money rolls over a magnetic head that detects magnetic colors of emblems and images by comparing the detected signal with an appropriately specified reference value - in order to determine the authenticity of the banknote in circulation, depending on results

comparisons. However, the magnetic head tends to become contaminated with paint residues, which leads to incorrect detection. In addition, the counterfeiter can make such money, which, having similar magnetic colors, will mislead the machine.

Currently, modern paper money identifiers, as a rule, are based on the use of various kinds of LEDs (light-emitting diodes) as a source of various light emissions, designed to check the parameters of various paper money. Figures 9 and 10 show a prototype of a paper money identifier (banknote). This design of a paper money identifier includes a first linear light source A1 and a second linear light source A2 located on two sides above the test area F1, a certain number of photosensors C1 mounted between said linear sources A1 and A2, and a first optical element B1 installed under the C1 photo sensors. When the document (banknote) E1 arrives at the input of the paper money identifier, the specified input is blocked, and the paper rolls begin to advance the document E1 through the test zone F1. In this case, the linear light sources A1 and A2 are tuned to emit pulsating light onto the document E1, the first optical element B1 focuses the reflected light on the photosensors C1, and the photo sensors C1 feed back a certain indicator at a given point in time of information access. This specific indicator is a sign of a normal DIS (two impulse reduction) of the color density of the scanned surface of the document E1. The described method should provide verification of the entire document. In addition, an additional light source A4 and a fourth optical element B4 can be installed on the other side. The additional light source A4 is configured to emit penetrating light passing through the document E1 to check the permeability of the document E1. After scanning, the paper money identifier work node receives various indicators generated by various light sources and compares these indicators with the reference indicators of the storage device, thus determining whether to accept or reject document E1. According to this inductive method, it is necessary to check the composite tape blocks of the E1 document and compare the scanned indicators generated by the specified tape blocks with the reference indicators for further calculations. According to this design, in each of the linear light sources A1 or A2, multi-colored light-emitting diodes A3 are used to obtain a verification

lights of various colors. Further, the second optical element B2 and the third optical element V3 are installed in front of the first linear light source A1 and in front of the second linear light source A2 to correct the corresponding exit angle of the light radiation. The location of the linear light sources A1 and A2, the optical elements B1, B2 and B3 and the photos of the sensors C1 must be carefully calculated so that the detected signals can be compared with the reference indicators for further accurate calculations.

The described prototype of the paper money identifier has a number of disadvantages, namely:

1. Since the A3 LEDs in each linear light source A1 or A2 are spaced apart from each other, the A3 LEDs do not allow the document E1 to be checked in the same test area F1 with light of different colors and can only use the usual estimate of all scanned light to calculate surface color reaction of document E1.

2. Different documents (banknotes) E1 of different countries have different characteristics that make it difficult to fake. Therefore, the main node must be equipped with a high-performance database for storing the specified reference information required for comparison.

3. This identification method is based on the use of light-emitting diodes A3 for emitting light of different colors on the document E1 and photosensors C1 with the first optical element B1 to capture the light reflected from various tape blocks of the document E1, for comparison with the reference values. The alignment accuracy between the light-emitting diodes A3, the photosensors C1 and the optical elements B1, B2 and VZ is very important.

4. After scanning various tape blocks of the E1 document with different color shades of light from the light-emitting diodes A3, a matrix accuracy calculation procedure is required to verify the authenticity of the E1 document. This calculation procedure requires a certain period of time, which is not acceptable for vending machines that verify the authenticity of paper money.

5. The complex design of this sample paper money identifier is characterized by a large number of details, which leads to increased production costs.

Further, AKAs (automatic cash registers) or banknote counters used in the banking system are usually based on the use of ultraviolet lamps to scan paper money. Ultraviolet lamps are not suitable for use in a banknote identifier intended for a vending machine. When a banknote identifier with ultraviolet lamps is used in a street vending machine, humid air may pass through the gap between the lamp bulb and the lampholder, causing a short circuit. Moreover, the bulb of the ultraviolet lamp quickly weakens during operation. Moreover, an ultraviolet lamp consumes a lot of electricity and emits a lot of thermal energy during operation. Finally, the ultraviolet lamp has a large side surface and short life and is easily damaged.

SUMMARY OF THE INVENTION

The present invention was developed in connection with the above circumstances.

According to one aspect of the present invention, the lens module includes a housing, a lens element mounted on an upper side of the housing, and a cover worn on the housing to prevent the lens element from falling out. The housing from its upper side is provided with a flange, an orientation groove at one end of the flange and several mounting holes located asymmetrically at both ends of the housing from the upper side inside the space enclosed by the flange. The lens element is inserted into the space enclosed by the flange, having a protrusion intended for installation in the alignment groove, and several mounting pins inserted into the corresponding mounting holes of the housing. Thus, the lens element is provided with an accurate and defined location between the housing and the cover.

According to another aspect of the present invention, the lens element has a certain number of flat protrusions protruding above the lower surface and appropriately inserted into the respective through holes of the housing with an exact orientation to the LEDs or sensors of the circuit board on which

a housing is installed, and a certain number of convex sections protruding above the upper surface, corresponding to flat projections. Therefore, the alignment of the lens element with the LEDs or sensors of the circuit board is achieved automatically after mounting the lens module on the circuit board, and an additional alignment operation is not required.

According to another aspect of the present invention, the lens module is designed for use in a banknote receiver. During operation, the flat protrusions and convex portions of the lens element of the lens module mounted on the circuit board of the light-emitting banknote receiver unit direct light of different wavelengths from the LEDs of the attached circuit board to the convex sections of the lens element of the lens module mounted on the circuit board of the light-sensing banknote receiver unit, that the flat protrusions of the lens element of the lens module mounted on the circuit board of the light-receiving unit focus the corresponding rays veto on sensors attached to the circuit board bill validator. This design prevents interference between light beams emanating from different LEDs, increasing identification accuracy in the banknote receiver.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a three-dimensional image of the lens module in accordance with the present invention, with a spatial separation of the parts.

Figure 2 corresponds to figure 1 from a different angle.

Figure 3 corresponds to figure 1, representing a lens element mounted in the flange of the housing.

Figure 4 is a front view of the lens module assembly in accordance with the present invention.

5 is a three-dimensional image of the lens module and circuit board in accordance with the present invention, with a spatial separation of the parts.

6 is a schematic sectional view illustrating the use of the present invention in a banknote receiver.

Fig.7 is an expanded view of one node of Fig.6.

Fig. 8 is a sectional view of one assembly of a banknote receiver incorporating the present invention.

FIG. 9 is a schematic diagram illustrating a construction of a paper money identifier in accordance with a prototype. FIG.

Figure 10 is a schematic diagram illustrating a device of a linear light source in accordance with the prototype.

DETAILED DESCRIPTION OF THE INVENTION

As shown in figures 1-4, the lens module in accordance with this invention consists of a housing 1, the lens element 2 and the cover 3.

The housing 1 of the lens module is a narrow, oblong part, on the upper side of which there is a flange 11. In the housing linearly in a row there is a certain number of through vertical holes 12 covered by the flange 11. On the upper side of the housing inside the space enclosed by the flange 11, several mounting holes are made 13. They are located asymmetrically from two opposite sides relative to the row of through holes 12. The housing is provided with an orientation groove 111 at one end of the flange 11; several mounting pins 112, asymmetrically located on two opposite walls of the flange 11 and protruding above the flange 11; several mounting elements 14, symmetrically located on two opposite sides of the housing and designed to secure the lens module on the circuit board; several guide grooves 15, made symmetrically on two sides of the housing so that their width gradually decreases in the direction from its upper side to its lower side; several locking tongues 16, protruding respectively from two opposite sides of the housing, in each of the guide grooves 15, and on each locking tongue 16 there is a bevel 161 on top. The housing also has a certain number of bottom receiving holes 17 on the lower side, respectively, the number of through holes 12 and several bottom mounting pins 18 for fastening to the circuit board.

The lens element 2 is installed on the upper side of the housing 1 inside the flange 11. It has a narrow oblong-flat base 21, equipped with a protrusion 211 located at one end of the base 21 and intended for installation in the alignment groove 111 of the flange 11 of the housing 1. A certain number of convex sections 22 protrude from the upper side above the surface of the base

21, and a certain number of cylindrical flat protrusions 23 protrude from the lower side above the surface of the base 21, being appropriately inserted into the through holes 12 of the housing 1. The base 21 is also provided with several mounting pins 24 inserted into the corresponding mounting holes 13 of the housing from its lower side one.

To prevent the lens element 2 from falling out on the housing 1, a cover 3 is fitted having a certain number of through holes 31 corresponding to the convex portions 22 of the lens element 2. The cover 3 is also provided with a lower recess 32, which includes the flange 11 of the housing 1 and the lens element 2 located inside flange 11; several mounting holes 321, made on its lower surface inside the lower recess 32 and correspondingly mating with the mounting pins 112 of the housing 1; and several clamping eyes 33, extending downward from its two opposite sides and correspondingly entering into the guide grooves 15 of the housing 1. Each of the clamping eyes 33 has a locking slot 34, each of which engages with a corresponding locking tongue 16 of the housing 1.

In the assembly process of the lens module, the lens element 2 is placed inside the flange 11 by pressing so that the protrusion 211 and the mounting pins 24 fit respectively into the alignment groove 111 of the mounting holes 13 of the housing 1, introducing the flat protrusions 23 into the through holes 12 of the housing 1. Thanks the design correspondence between the protrusion 211 and the alignment groove 111 and, respectively, between the mounting pins 24 and the mounting holes 13 in the present invention prevents the incorrect installation of the lens element 2.

After installing the lens element 2 in the housing 1, put the lid 3 on the housing 1, inserting the clamping eyes 33 into the guide grooves 15 of the housing 1 and engaging the locking slots 34 with the corresponding locking tabs 16 of the housing 1. Due to the bevel 161, each locking tab 16 has clamping the eyes 33 are easily engaged with the locking tabs 16 of the housing 1 in order to fix the lens element 2 in the housing 1, while holding respectively the convex portions 22 of the lens element 2 in the through holes 31 of the cover 3.

As shown in FIGS. 5 and 6, the lens module in accordance with this invention can be easily mounted on a circuit board 4 having

a certain number of LEDs 41 or sensors 42 installed on it in accordance with the TPM (Surface Mount Technology).

During installation, the bottom mounting pins 18 of the housing 1 are respectively inserted into the mounting holes 43 of the circuit board 4, thereby introducing LEDs 41 or sensors 42 into the bottom receiving holes 17 of the housing 1. Then, the mounting elements 14 of the housing 1 are appropriately connected to the corresponding threaded holes 44 the circuit board 4 with the corresponding screws 45. As a result of such mounting, the LEDs 41 or the sensors 42 are accordingly oriented to the through holes 12 of the housing 1. Based on the foregoing, the lens m The module can be easily mounted on circuit board 4, and its thickness does not matter for mounting the lens module.

In real practice, two lens modules are mounted respectively on two circuit boards 4 (on one is a set of LEDs 41, and on the other is a set of sensors 42), and these two circuit boards and two assembly units of lens modules are placed opposite each other. One circuit board and an assembly unit of the lens module are used as the light emitting unit, while the other circuit board and the related assembly unit of the lens module are used as the light receiving unit. Light emitting and light receiving units are installed in the banknote receiver (not shown) from two sides with respect to the banknote supply channel. When the LEDs 41 of the light-emitting unit are turned on, they emit light through the flat protrusions 23 and the convex portions 22 towards the convex portions 22 of the lens module of the light-receiving unit. Due to the property of the convex portions 22 of the lens module of the light-emitting element, parallel light rays pass to the convex portions 22 of the lens module of the light-receiving unit, and then focused on the respective sensors 42 (see Fig. 7), focused by the corresponding flat protrusions 23 of the lens module of the light-receiving unit.

Further, the LEDs 41 may be provided with composite light emitting diode chips for emitting light of various wavelengths, for example: red light with a wavelength of 615-635 nm; green light with a wavelength of 515-532 nm; blue light with a wavelength of 460-475 nm; and characterized by high permeability, infrared light of the first range with a wavelength of 850 nm or infrared light of the second range with a wavelength of 940 nm. By adjusting the circuit board 4 of the light-emitting unit, an intense pulse

light radiation of different wavelengths can be directed to the same section of the checked banknote 6, so that all the security features of the banknote 6 can be examined. The checked banknote 6 can be a bill, a ticket, a paper bill, a security, etc., suitable for use in vending machines.

On Fig shows a view in section of one example of the application of the present invention in the receiver 5 banknotes in a vending machine. When the banknote 6 is inserted into the banknote supply channel 51 in the banknote receiver 5, the banknote receiver 5 feeding mechanism 52 draws the banknote 6 through the slot between the two lens modules (the lens module of the light-emitting unit and the lens module of the light-receiving unit). In this case, the circuit board 4 of the light-emitting unit instructs the LEDs 41 to emit intense pulsed light radiation of various wavelengths through the attached lens module in the direction from its flat protrusions 23 to its convex portions 22, and the convex portions 22 of the lens module of the light-emitting element direct incoming light from LEDs 41 to the detected portion of the banknote 6. Passing through the detected portion of the banknote 6, the light beam of each of the LEDs 41 goes to the corresponding convex section 2 2 of the lens module of the light pickup unit, and then focuses by the attached flat protrusion 23 to the attached sensor 42. Excited by the light beams of the LEDs 41, the sensors 42 generate a corresponding signal for comparison with a predetermined reference value that the banknote receiver control unit 5 is set to determine the authenticity of the banknote 6 .

The authentication of the banknote 6 by emitting light of different wavelengths can be carried out in one of two different ways. In the first method, light of different wavelengths from the LEDs 41 is emitted to the same detectable portion of the banknote 6, and the detectable portion of the banknote 6 exhibits a different transmission degree for comparison with a predetermined reference value in order to determine the authenticity of the banknote 6. In the second method, specific penetrated light occurs from the emission of light of different wavelengths due to the effect of the color of the banknote 6, and the sensors 42 pick up this penetrated light for comparison with a predetermined reference value in order to determine truly 6 minute banknote.

As indicated above, the invention is characterized by the following

As indicated above, this invention is characterized by the following features:

1. By orienting the protrusion 211 and the mounting pins 24 of the lens element 2 to the orientation groove 111 and the mounting holes 13 of the housing 1, then inserting the lens element 2 into the flange 11 of the housing 1 and attaching the cover 3 to the housing 1, teach the lens module assembly, while the lens element 2 is accurately and definitely fixed from falling out between the housing 1 and the cover 3. After installing the lens module on the circuit board 4, the flat protrusions 23 of the lens element 2 are respectively and precisely oriented to the LEDs 41 or sensors 42 of the circuit board 4 in the desired direction.

2. Thanks to the mounting elements 14 and the bottom mounting pins 18 of the housing 1, the lens module can be easily mounted on the circuit board 4 so that the LEDs 41 or the sensors 42 of the circuit board 4 respectively fit into the bottom receiving holes 17 of the housing 1, being correctly oriented to flat protrusions 23 of the lens element 2. When using the lens module in the banknote receiver 5 of the vending machine, light of different wavelengths from the LEDs 41 is directed to the respective sensors 42 by convex portions 22 of the lens element 2 without interference entsii. In this case, the sensors 42 can accurately perceive light of different wavelengths passing from the LEDs 41 through the banknote 6.

3. The lens element 2 is provided with an accurate and defined location between the housing and the cover. After installing the lens module on the circuit board 4, the flat protrusions 23 of the lens element 2 are precisely oriented to the LEDs 41 or the sensors 42 of the circuit board 4. Therefore, no further adjustment is required between the lens element 2 and the LEDs 41 or the sensors 42 of the circuit board 4 .

Although a specific embodiment of the invention is described herein for illustrative purposes, various modifications and improvements to the device may be made without departing from the spirit and scope of the invention. Therefore, this invention should not be limited by anything other than the attached claims.

Claims (9)

1. The lens module, comprising a housing having an upper side, a lower side, two opposite lateral sides, a flange on the upper side, a certain number of through vertical holes made linearly in a row and covered by the specified flange, several mounting holes made on the upper side and located from two opposite sides relative to the specified through vertical holes inside the space covered by the specified flange, several mounting elements located symmetrically with two opposite directions and intended for attachment to a circuit board, a plurality of guide grooves disposed symmetrically on two opposite sides, and a number of locking tabs extending respectively from two opposite sides of each of said guide grooves; a lens element having a narrow oblong-flat base mounted on the upper side of the specified housing inside the specified flange, and the specified flat base has an upper side and a lower side, a protrusion located at one end of the flat base and intended to be installed in the specified orientation groove of the specified flange of the specified body, a certain number of convex sections protruding from the upper side above the surface of the specified flat base, a certain number of flat protrusions, protruding x at the lower side surface of said flat base, being appropriately inserted into the through holes of said housing, and multiple mounting pins on the bottom side of said flat base are inserted into the corresponding insertion holes of said body; and a lid worn on said housing for fixing said lens element, said lid having a certain number of through holes corresponding to convex portions of said lens element, a lower recess in which said flange of said housing and said lens element inside said flange enter, and several clamping eyes extending downward from its two opposite lateral sides and correspondingly entering into said guide grooves of said housing, m in each of said clamping lugs has a locking slot meshing with a corresponding stop lug of said body. 2. The lens module according to claim 1, in which the mounting holes of the specified housing are located asymmetrically from two opposite sides relative to the specified through holes. 3. The lens module according to claim 1, in which the specified housing also has several mounting pins located asymmetrically on both sides of the specified flange; the specified cover has several mounting holes made in the specified lower recess and correspondingly mating with the mounting pins of the specified housing. 4. The lens module according to claim 1, wherein said guide grooves are gradually reduced in width in a direction from the upper side of said housing to the lower side of said housing. 5. The lens module according to claim 1, in which each of these stop tabs is equipped with a bevel for guiding said clamping eyes to the locking position. 6. The lens module according to claim 1, in which the specified housing has on its lower side several bottom mounting pins for fastening to the circuit board. 7. The lens module according to claim 1, wherein said flat protrusions of said lens element are cylindrical. 8. The lens module according to claim 1, in which the specified housing has on its lower side a certain number of bottom receiving holes corresponding to the specified through holes to accommodate surface mounted light emitting diodes / sensors mounted on a circuit board. 9. The lens module according to claim 1, wherein said mounting elements of said housing are fixedly attached to the threaded holes of the circuit board with corresponding screws.