JP3007244B2 - Radiation temperature detector - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiation temperature detector which is provided in an indoor unit or the like of an air conditioner and detects the radiation temperature of an indoor wall or the like in a non-contact manner.

[0002]

2. Description of the Related Art Generally, for example, in an air conditioner,
The indoor unit is equipped with an air temperature detector that detects the indoor air temperature and a radiant temperature detector that detects the radiant temperature of the wall and the like, and the indoor comfortable temperature control is performed based on these two detection signals. ing.

A conventional radiation temperature detector is disclosed in
As shown in JP-A-187130, a radiant heat absorbing plate and one temperature detecting element are provided in a heat insulating case having only an open front surface, and the front surface of the radiant heat absorbing plate has a spectral surface of the human skin. A coating material that almost matches the reflectance is formed, the opening is covered with a thin film that transmits infrared rays, and a horn-shaped reflecting tube or reflecting mirror with aluminum plating or gold plating is provided on the front surface. There is something.

In this method, a radiant heat ray from a part of the room is selectively incident by a reflecting tube or a reflecting mirror, and an infrared ray corresponding to a radiant heat ray from a wall or the like is transmitted through an infrared ray transmitting thin film to an infrared ray in front of the radiant heat absorbing plate. The radiation temperature in a predetermined area in the room is detected by absorbing the light into the absorbent paint layer and transmitting the temperature from the radiation heat absorbing plate to the temperature detecting element for detection.

[0005]

In order to control the comfortable temperature in a room with an air conditioner, not only the air temperature (air flow temperature) but also the radiation temperature from a wall or the like has an influence on the human sensed temperature. Well known.

For this purpose, it is necessary to detect the radiation temperature distribution in the room. However, the radiation temperature detector described above
Since the radiation temperature in a predetermined area in the room is detected by the temperature detecting elements, in order to detect the radiation temperature distribution in the room, a plurality of radiation temperature detectors are provided and directed in different directions. It is necessary to construct a unit or a system capable of performing indoor detection scanning with one radiant temperature detector.

[0007] In the former case, the direction of each radiation temperature detector must be adjusted, which causes a problem that it is complicated and expensive. In the latter case, it is necessary to separately provide a rotary drive device and the like, which also causes a problem that it is complicated and expensive.

SUMMARY OF THE INVENTION In view of the foregoing, it is an object of the present invention to enable a simple radiation temperature detector to accurately detect a radiation temperature distribution in a room.

[0009]

In order to achieve the above object, a radiation temperature detector according to the present invention comprises a printed wiring board provided with a plurality of temperature detecting elements on one side, and a convex lens portion facing the temperature detecting element. A light collecting plate having a group and a separator for individually partitioning the temperature sensing elements and ensuring a spatial distance between the printed wiring board and the light collecting plate are provided.

[0010]

According to the above construction, the infrared rays incident from the respective convex lenses of the light collector reach the temperature detecting elements on the printed wiring board independently of each other through the respective openings of the separator. For example, the radiant heat rays from the direction A are focused from the convex lens A to the temperature detecting element A on the printed wiring board and the vicinity thereof through the opening A of the separator. As a result, the temperature detecting element A detects the absorbed heat according to the radiant heat rays from the A direction. Thus, the radiation temperature of the floor or wall in the direction A can be selectively detected.

Similarly, the radiation temperature in the B, C, or D direction is selectively detected by the temperature detecting element B, C, or D, respectively, through the opening B, C, or D of the separator. Therefore,
The temperature distribution in the room can be easily known.

[0012]

Embodiments of the present invention will be described below in detail with reference to the drawings. The radiation temperature detector of the present invention is a simple radiation temperature detector provided in an indoor unit such as an air conditioner, and detects radiation heat from a floor, a wall, or the like in a non-contact manner by a temperature detection element.

As shown in the exploded perspective view of FIG. 1, the radiation temperature detector includes a plurality of temperature detection elements 7 ₁ , 7 ₂ , 7 ₃ ,.
.. and a printed wiring board 6 to which one temperature detecting element 8 for correction is attached, and the temperature detecting elements 7 ₁ , 7 ₂ , 7 ₃ ,
... separator-4 for independently guiding radiant heat rays to
When this separator - the opening of the motor -4 5 _1, 5 _2, 5 _3, -
.. Are formed from the light collector 1 provided with lenses 2 ₁ , 2 ₂ , 2 ₃ ,...

A connector 12 is mounted on the printed circuit board 6, and a screw hole 9 is provided at the time of assembly.

The temperature detecting elements (7 ₁ , 7 ₂ , 7 ₃ ,..., 8) are composed of a surface-mounted chip thermistor or a thermocouple for detecting temperature. Soldered. Unlike the other temperature detecting elements 7 ₁ , 7 ₂ , 7 ₃ ,..., The temperature detecting element 8 for correction is designed so as not to be irradiated with radiant heat rays.

For example, in FIG. 2, a recess 10 facing the printed wiring board 6 is provided below the end of the separator 4 to assemble the printed wiring board 6 with the separator 4.
The temperature detecting element 8 for correction is located in the recess 10.

FIG. 3 shows a temperature detecting element 8 for correction.
Resin-based adhesive 14 such as acrylic which does not transmit infrared rays
An embodiment is shown in which the temperature sensing element 8 covered with the adhesive is positioned in a recess 15 provided below the end of the light collector 1. In this embodiment, the volume of the separator-4 can be reduced and the structure can be simplified as compared with the embodiment of FIG.

The light collector 1 is integrally formed of an infrared transmitting resin such as polyethylene or polypropylene, and the separator 4 is formed integrally of a resin such as acrylic which does not transmit infrared light. If the inner cross section of the opening 5 of the separator 4 is coated with aluminum plating or nickel plating having a high infrared reflectance, the amount of infrared rays reaching the temperature detecting element 7 can be increased, and the detection sensitivity can be further increased. it can.

The printed wiring board 6 is attached to the light collector 1 by mounting screws 13 and the separator 4 is placed at a predetermined position between the light collector 1 and the printed wiring board 6. And is held in a form retained by the The light collector 1 is attached to the indoor unit of the air conditioner to which the radiation temperature detector is attached by screws or the like through the attachment hole 3.

The infrared rays incident from the convex lens portion 2 ₁ to 2 _N-1 of the light collecting plate 1, separator - a plurality of openings 5 ₁ to 5 of the motor -4
Through _N-1 , the temperature detecting element 7 ₁ on the printed wiring board 6
Reaches ~ 7 _N-1 . Here, N represents the total number of the temperature detecting elements 7 and 8 provided on the printed wiring board 6.

The temperature detecting element 8 for correction fits into the recess 10 of the separator 4 (FIG. 2), and
4, the ambient temperature of the temperature detecting element group 7 on the printed wiring board 6 can be detected without being affected by incident infrared rays.

The convex lens portion 2 ₁ ~2 _N-1 enters the radiant heat rays from different directions of the floor or wall or the like, the corresponding temperature detection element 7 ₁ ~7 _N-1 is absorbed heat corresponding to the radiation heat ray intensity Is detected. By correcting the output with the output of the temperature detecting element 8 for ambient temperature correction, the radiation temperature of the floor, wall, etc. in the direction of each convex lens can be independently and accurately detected.

Here, the correction processing means that the temperature detecting element 7
Is to detect the temperature in the case by the detecting element 8 and to detect the radiant heat from the outside by detecting the temperature in the case by detecting the temperature as the sum of the temperature in the case and the radiant heat from the outside. It is.

As shown in FIG. 6, the positional relationship and structure of the printed wiring board 6, the light collector 1 and the separator-4 are such that the opposed temperature detecting elements 7 are located at the focal position U of the convex lens unit group 2. By adjusting the dimensions, the radiant heat rays can be efficiently absorbed by the temperature detecting element 7. here,
R represents a horizontal axis of the detection surface, P represents a vertical axis, Q represents an optical axis of the convex lens 2, and T and S represent optical paths of incident infrared rays.

FIG. 4 shows an embodiment of a device for improving the detection sensitivity. Compared to the total pattern area of the soldering section 19 to which the electrode section 18 of the temperature detecting element 8 for temperature correction on the printed wiring board 6 is soldered and the wiring pattern section 20 shown in FIG. 4B, a soldering portion 22 to which the electrode portion 21 of the temperature detecting element 7 is soldered and a wiring pattern.
The wiring pattern area of the sum of the wiring portions 23 is increased so that the temperature detecting element 7 can efficiently detect the radiant heat rays reaching the printed wiring board 6.

Here, the reason for increasing the wiring pattern area is that since the conductor is a metal body, it has a higher thermal conductivity than a plastic body or a ceramic body of the substrate. 7

Reference numerals 17 and 24 denote respective wiring patterns.
And through-holes for electrically connecting and connecting the wiring patterns corresponding to the respective wiring patterns routed to the back surface of the printed wiring board 6. That is, since the circuit wiring is formed on the back surface of the printed wiring board 6 and components are mounted on the front surface, through holes are used to connect the pattern on the front surface to the circuit pattern on the back surface. 17 and 24 are provided.

FIG. 5 shows an embodiment of a device for improving the detection sensitivity. A soldering part 22, a wiring pattern part 23 and a through hole 24 are provided for the two electrode parts 21 of the temperature detecting element 7 on the printed wiring board 6, respectively. Another wiring pattern 26 is provided around or near a predetermined insulating distance from these live parts to increase the efficiency of collecting radiant heat rays. The present invention is not limited to the circumferential wiring pattern, and FIG. 9 shows an embodiment of the square wiring pattern.

FIG. 7 shows an embodiment for improving the detection sensitivity. FIGS. 4 and 5 show that the radiant heat rays passing through the convex lens portion 2 reach the entire area of the large wiring pattern portion 23 of the temperature detecting element 7 and another wiring pattern 26 provided around or around the large wiring pattern portion 23. FIG. 3 shows a diagram in which the focal position of the convex lens portion 2 is set farther than the temperature detecting element 7. Here, R is the horizontal axis of the detection surface, P is the vertical axis, Q
Represents the optical axis of the convex lens 2, and T and S represent optical paths of incident infrared rays.

FIG. 9 shows an embodiment of a device for improving the detection sensitivity. That is, a paint containing a mixture of a tetrafluoroethylene resin and titanium oxide, which substantially matches the spectral reflectance of the human skin, is applied to the wiring pattern around the electrode portion 21 and the soldering portion 22 of the temperature detecting element 7. 23, and the surrounding insulating space 25 and the separate wiring pattern 26 around it, that is, the area surrounded by a, b, c, and d in FIG. It is applied to the area excluding the portion to be radiated by a silk printing technique or the like, so as to detect a radiant temperature equivalent to that felt by a person with respect to radiant heat such as a floor or a wall. The portion 27 on the printed wiring board 6 in FIG. 8 corresponds to the application portion in this embodiment.

FIG. 8 shows the printed wiring board 6 and the light collector so that the radiant heat rays passing through the convex lens portion 2 are focused on the coating portion 27 and the focal position U of the convex lens 2 is located on the coating portion 27. The positional relationship and the structural dimensions of 1 and separator-4 are matched. Where R is the horizontal axis of the detection surface,
P represents the vertical axis, Q represents the optical axis of the convex lens 2, T and S
Indicates an optical path of incident infrared light.

A resin paint that does not transmit infrared rays, such as acrylic, is applied to an edge portion 28 in a region surrounded by the opening 5 of the separator 4 in FIG. 9 by a silk printing technique or the like. Each of the temperature sensing elements 7 in each of the openings 5 adjacent to each other is not affected by the heat absorbed by the other temperature sensing elements. 28 on the printed wiring board 6 in FIG. 8 corresponds to the application portion.

FIG. 10 shows an embodiment of the detection accuracy improving specification. In order to detect indoor radiation temperature distribution, FIG.
As shown in FIG. 1, the radiant temperature detector 30 of the present invention is mounted at a position near the front of the indoor unit 31 of the air conditioner and obliquely downward as shown in FIG.

The lowermost central convex lens 1-3 in the array of convex lens groups is used to detect the nearest floor surface in the front direction of the indoor unit 31. And
1-1 is used for detecting the side wall, and 1-5 is used for detecting the side wall. 3-3 at the center of the array is used for detecting the floor Y in the middle of the room, and 5-1, 5-2, and 5-3 at the upper end of the array are used to detect the farthest walls ヲ, ワ and mosquitoes, respectively.

Since the intensity of the radiant heat ray reaching the radiant temperature detector 30 is inversely proportional to the square of the distance, the convex lens used for detecting a distant position has a larger lens diameter to reduce the detection sensitivity due to the detection distance. Restrained. That is, in the arrangement of the convex lenses, the lens diameter becomes larger as the lens is farther to the left and right with respect to the center, and the lens diameter is larger as the lens is farther upward with respect to the lowest.

FIGS. 12, 13 and 6 show one embodiment. In the radiation temperature detector of the present invention, the light collector 1
Has a substantially planar structure with R in FIG. 6 as a plane axis, and each convex lens group 2 is configured to face a different detection direction in the room. Since the light collector 1 is integrally formed,
If the detection surface has a planar structure, the detection angle of each lens can be uniquely determined by the optical axis of each lens, and there is an advantage that design and manufacturing and assembly can be simplified.

In the case of the lens arrangement of the embodiment of FIG. 10, the optical axis of each lens is from lens 1-X to 5-X (where X = 1).
For the vertical direction toward the 5), as shown in FIG. 12, the lens 3-X of the optical axis Q _3-X coincides with the axis perpendicular P to the plane axis R, both ends of the lens 1-X and the lens 5-X
, The angle θ between the optical axis and the axis P in different directions increases. Also with respect to the horizontal direction from the lens X-1 to the lens X-5 (provided that X = 1 to 5), as shown in FIG. 13, a vertical optical axis Q _X-3 of the lens X-3 is in the planar axes R Lens P at both ends
1 and X-5, the angle θ between the optical axis and the axis P in different directions increases.

As shown in FIG. 6, the central axis of each opening 5 of the separator-4 coincides with the optical axis Q of each convex lens 2, and the infrared light passing through each convex lens surface is uniformly emitted. It passes through each opening 5.

This means that the detection efficiency of each temperature detecting element 7 is improved, and at the same time, the optical axis of the infrared light passing through the detecting surface of the light collector 1 is gathered at the center. This has the advantage that the required area of the wiring board 6 can be small.

[0040]

As described above, the radiation temperature detector according to the present invention comprises a printed wiring board provided with a plurality of temperature detecting elements on one side, and a condensing plate having a convex lens group individually opposed to the temperature detecting elements. And a simple configuration that separates the temperature sensing elements and secures a spatial distance between the printed wiring board and the light collector, so that it is inexpensive, easy to manufacture and assemble, and has good detection accuracy. This has the effect.

In order to detect the temperature distribution over a wide range, the optical axis of the lens and the guide hole of the separator must be arranged so that infrared rays from different directions reach a plurality of temperature detecting elements. The radiation temperature detector that detects a wide temperature distribution can be obtained by assembling the light collector with such a lens and the separator together with the printed wiring board. Can be

According to the second aspect of the present invention, the light collector is integrally formed of an infrared ray transmitting resin, and the separator is integrally formed of a resin which does not transmit infrared rays. It is easy to manufacture and assemble.

According to a third aspect of the present invention, the printed wiring board, the light collector, and the separator are arranged such that each temperature detecting element facing each convex lens is located at each focal position of the convex lens group of the light collector. Since the positional relationship and the thickness of the separator are set, it is easier to manufacture and assemble.

According to a fourth aspect of the present invention, another wiring pattern is formed around or near the electrode pattern of the plurality of temperature sensing elements facing the convex lens group on the printed wiring board. Thus, the heat collection sensitivity of the radiation temperature can be increased.

According to a fifth aspect of the present invention, the focus of the printed wiring board, the light collector, and the separator is set so that each focal point of the convex lens unit group is farther than each position of the plurality of temperature sensing elements facing each other. Since the positional relationship and the thickness of the separator are set, the heat collecting sensitivity can be further improved.

According to a sixth aspect of the present invention, the pattern of the electrode portions of the plurality of temperature sensing elements facing the convex lens portion group of the light collector on the printed wiring board is provided at a part, around, or in the vicinity thereof. Since a paint containing a material substantially matching the spectral reflectance of the skin of the human body is applied, a radiation temperature equivalent to that felt by a human can be detected.

According to a seventh aspect of the present invention, each focal point of the convex lens unit group opposes a part of the pattern of the electrode portions of the plurality of temperature sensing elements, or each of the paint application portions around or near the electrode portions. In addition, since the positional relationship between the printed wiring board, the light collector and the separator and the thickness of the separator are set, the heat collection sensitivity can be further improved.

According to the present invention, a resin paint that does not transmit infrared rays is applied to the edges of each area on the printed wiring board which is individually partitioned by the separator. There is no mutual interference of temperature sensing elements.

According to a ninth aspect of the present invention, the convex lens portion group of the light collector and the plurality of temperature sensing elements facing the convex lens portion group are arranged in a lattice pattern, and the center of one side of the array of the convex lens portion group is arranged. The convex lens portion, which is farther in the horizontal and vertical directions than the lens diameter of the convex lens portion, has a larger lens diameter, so that the influence of the detection distance can be suppressed and the indoor radiation temperature can be detected with high accuracy.

According to a tenth aspect of the present invention, the optical axis of at least the peripheral convex lens portion of the convex lens portion group arranged in a lattice shape of the light collector is perpendicular to the plane of the flat portion of the light collector. Since it is set so as not to be changed, the design of the detection direction of the present radiation temperature detector is easy, and the required area of the printed wiring board can be reduced, so that the cost can be reduced.

In the eleventh aspect, the optical axis of each convex lens unit group, which is perpendicular or inclined at a predetermined angle with respect to the plane of the flat portion of the light collector, faces the convex lens unit group. Since the central axes of the openings of the respective separators are made to coincide with each other, it is easy to design the detection direction of the radiation temperature detector, and the required area of the printed wiring board can be reduced and the cost can be reduced. ing.

According to a twelfth aspect of the present invention, a plurality of first temperature detecting elements, a second temperature detecting element for detecting an ambient temperature to correct the output of the first temperature detecting elements,
Since the shielding means for shielding the temperature detection element from being irradiated with infrared rays is provided, the radiation temperature distribution in the room can be accurately detected.

According to a thirteenth aspect, the shielding means includes:
Since there is a recess provided in a part of the separator, the accuracy of ambient temperature correction is improved.

According to a fourteenth aspect, the shielding means includes:
Since a resin-based adhesive applied to the outer periphery of the second temperature detecting element and not transmitting infrared rays is provided, the accuracy of ambient temperature correction is improved.

According to a fifteenth aspect, the pattern area of the electrode portions of the plurality of first temperature sensing elements facing the convex lens portion group on the printed wiring board does not face the convex lens portion group. Since the pattern area of the electrode portion of the second temperature detecting element for correction is formed to be larger, the heat collecting sensitivity is further increased.

[Brief description of the drawings]

FIG. 1 is an exploded perspective view showing a basic configuration of a radiation temperature detector of the present invention.

FIG. 2 is a sectional view showing an embodiment of a radiation temperature detector according to the present invention.

FIG. 3 is a sectional view showing another embodiment of the present invention.

FIG. 4 is a view showing an example of a pattern of a printed wiring board for mounting a temperature detecting element according to the embodiment of the present invention.

FIG. 5 is a diagram showing an example of a pattern of a printed wiring board for improving detection sensitivity used in an embodiment of the present invention.

FIG. 6 is a cross-sectional view showing an embodiment in which the focus of the convex lens of the light collector is adjusted to the temperature detecting element in the present invention.

FIG. 7 is a cross-sectional view showing an embodiment of the present invention in which the focus of the convex lens of the light collector is set farther from the temperature detecting element to improve sensitivity.

FIG. 8 is a cross-sectional view showing an embodiment in which the focus of the convex lens of the light collector is adjusted to the paint layer in the present invention.

FIG. 9 is a plan view showing an embodiment of a square pattern of a printed wiring board according to the present invention.

FIG. 10 is an external perspective view showing an example of mounting a radiation temperature detector embodying the present invention.

FIG. 11 is a diagram showing an example of an indoor arrangement of a radiation temperature detector embodying the present invention.

FIG. 12 is a diagram showing each optical axis of a convex lens group arranged in a vertical direction according to the present invention.

FIG. 13 is a diagram showing each optical axis of a convex lens group arranged in a horizontal direction according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Condenser plate 2 Convex lens part group 3 Mounting hole 4 Separator 5 Opening 6 Printed wiring board 7 Temperature detection element for infrared detection 8 Temperature detection element for ambient temperature detection 9 Screw stop hole 10 Provided in a separator Recessed recess 11 Lead wire outlet 12 Connector 13 Mounting screw 14 Resin-based adhesive that does not transmit infrared rays 15 Recess provided in light collector 16 Mounting screw 17 Through hole 18 Solder of temperature detecting element 8 Attachment part 19 Pattern soldering part 20 Pattern 21 Soldering part of temperature sensing element 7 22 Pattern soldering part 23 Pattern 24 Through hole 25 Insulation part 26 External pattern 27 Painted part 28 Resin which does not transmit infrared rays 29 Indoor 30 Radiant temperature detector 31 Indoor unit of air conditioner

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ identification code FI G01V 8/12 G01V 9/04 A (58) Investigated field (Int.Cl. ⁷ , DB name) G01J 5/02 G01J 5 / 10 G01J 5/48 G01J 1/00-1/46 G01V 8/10

Claims (15)

(57) [Claims] 1. A printed wiring board provided with a plurality of temperature detecting elements on one side, a light collector having a group of convex lenses individually opposed to the temperature detecting elements, and the printed wiring separately dividing the temperature detecting elements. A radiation temperature detector, comprising: a separator for securing a spatial distance between a substrate and the light collector. 2. The light collector according to claim 1, wherein the light collector is integrally formed of an infrared-transmitting resin, and the separator is formed integrally of a resin that does not transmit infrared light. 3. A radiation temperature detector according to claim 1. 3. The positional relationship between the printed wiring board, the light collector and the separator, and the separator so that each temperature detecting element facing each convex lens is located at each focal position of the group of convex lenses of the light collector. 2. The radiation temperature detector according to claim 1, wherein the thickness of the heater is set. 4. A radiation pattern, wherein another wiring pattern is formed around or near a pattern of electrode portions of the plurality of temperature sensing elements facing a group of convex lenses on the printed wiring board. The radiation temperature detector according to claim 1, wherein the heat collection sensitivity is increased. 5. The positional relationship between the printed wiring board, the light collector, and the separator so that each focal point of the convex lens portion group is farther than each of the positions of the plurality of temperature sensing elements facing each other. The radiation temperature detector according to claim 1, wherein the thickness of the tar is set. 6. A part of, a periphery of, or a vicinity of a pattern of electrode portions of the plurality of temperature sensing elements facing a convex lens group of the light collector on the printed wiring board.
2. The radiation temperature detector according to claim 1, wherein a paint containing a material substantially matching the spectral reflectance of human skin is applied. 7. The printed wiring so that each of the focal points of the group of convex lenses opposes a part of the pattern of the electrode part of the plurality of temperature sensing elements, or the respective paint-coated part around or in the vicinity thereof. The radiation temperature detector according to claim 1, wherein the positional relationship between the substrate, the light collector, and the separator and the thickness of the separator are set. 8. A resin paint which does not transmit infrared rays is applied to an edge in each area on the printed wiring board which is individually partitioned by the separator. 3. A radiation temperature detector according to claim 1. 9. The convex lens unit group of the light collector and the plurality of temperature sensing elements facing the convex lens unit group are arranged in a lattice, and the lens diameter of the convex lens unit at the center of one side of the array of the convex lens unit group. 2. The radiation temperature detector according to claim 1, wherein the lens diameter of the convex lens portion that is farther in the horizontal and vertical directions is larger than that of the radiation temperature detector. 10. An optical axis of at least a peripheral convex lens portion of the convex lens portion group arranged in a lattice shape of the light collector is set so as not to be perpendicular to a plane of a flat portion of the light collector. The radiation temperature detector according to claim 1, wherein: 11. An optical axis of each convex lens unit group formed so as to be perpendicular or inclined at a predetermined angle with respect to a plane of a flat portion of the light collector, and each of the separators facing the convex lens unit group. 2. The radiation temperature detector according to claim 1, wherein the central axes of the openings of the tar are matched. 12. A printed circuit board provided with a plurality of first temperature detecting elements on one side, and a second temperature detecting element for detecting an ambient temperature to correct the output of the first temperature detecting elements. (1) a light collector having a group of convex lenses individually opposed to the temperature detecting element, and a separator for separately partitioning the first temperature detecting element and securing a spatial distance between the printed wiring board and the light collecting plate; A radiation temperature detector, comprising: shielding means for shielding the second temperature detecting element from light. 13. The radiation temperature detector according to claim 12, wherein said shielding means has a recess provided in a part of said separator. 14. The radiation temperature detector according to claim 12, wherein the shielding means has a resin-based adhesive applied to an outer periphery of the second temperature detection element and not transmitting infrared rays. . 15. The pattern area of the electrode portions of the plurality of first temperature sensing elements facing the convex lens group on the printed wiring board, wherein the pattern area of the electrode portions of the plurality of first temperature sensing elements is not facing the convex lens group. 13. The radiation temperature detector according to claim 12, wherein the radiation temperature detector is formed to be larger than the pattern area of the electrode portion of the temperature detecting element.