JP7237452B2 - thermal alarm - Google Patents

Description

The present invention relates to a thermal alarm with a heat detection part.

Conventionally, a thermal alarm includes a main body provided with a substrate, and a heat detection unit installed on the substrate to detect heat. The heat detection section has a heat sensitive section such as a thermistor at its tip. A fire is detected when the heat of a hot airflow generated by a fire is transmitted to the heat-sensitive part and the output value from the heat-sensitive part exceeds a certain value. A main body of the thermal alarm is provided with a battery, a speaker, and the like, and when a fire is detected, a sound is generated from the speaker to notify the fire. The heat detector is arranged so as to protrude from the cover of the thermal alarm (see Patent Document 1, for example). In order for the heat sensitive part to receive heat with high efficiency, it is necessary to provide a space around it.

JP 2015-141568 A

However, the thermal alarm device of Patent Document 1 needs to be provided with a protector on the outside of the cover in order to protect the heat-sensitive part, which increases the thickness of the thermal alarm device. On the other hand, when it is attempted to reduce the thickness of the thermal alarm by arranging the heat sensitive part inside the cover, the heat of the hot air flow is absorbed by the members inside the main body and the cover, and the temperature of the hot air flow when passing through the heat sensitive part is reduced. decreases. As a result, the heat-receiving characteristics may deteriorate as compared with the conventional case where the heat-sensitive portion is arranged outside the cover and a protector is provided.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a thermal alarm capable of obtaining good heat receiving characteristics while making the thermal alarm thinner. . Here, the heat receiving characteristic refers to the difference between the actual temperature of the hot airflow and the temperature detected by the alarm. Obtaining good heat receiving characteristics means that the difference can be reduced.

The thermal alarm of the present invention comprises a main body, a cover having a communication hole and forming a communication space between itself and the main body, and a circuit provided on the main body so as to face the cover. and two heat detectors electrically connected to the substrate, each of which has a heat sensitive part at its tip and detects the heat of the airflow flowing into the circulation space through the circulation hole. wherein the cover has a bottom surface facing the body portion on which the substrate is provided, the bottom surface is provided with a vertical hole through which a vertical airflow flows, and each of the heat detection units includes the The heat-sensitive part is positioned closer to the outer periphery of the main body than a position where it is connected to the board, and is connected to the board so that the heat-sensitive part is positioned closer to the bottom surface of the cover than the board is . The body portion is provided with a structure accommodating portion having a shape that rises toward the bottom surface side of the cover and forming a space for accommodating a long structure on the side opposite to the bottom surface side, When the body portion is viewed from the bottom side, the heat sensitive portions of the two heat detection portions are arranged on a line segment passing through the center of the body portion so as to sandwich the center of the body portion. The portion extends from the center side of the main body portion toward the outer peripheral side in a direction orthogonal to the line segment passing through the center of the main body portion, and the heat sensitive portion of each heat detection portion is , are arranged outside the outer edge of the substrate.

Further, in the above thermal alarm, a plurality of the vertical holes are provided in the bottom surface of the cover, and the heat sensitive parts of the respective heat detection parts are arranged to face the respective vertical holes.

Advantageous Effects of Invention According to the present invention, it is possible to provide a thermal alarm whose thickness is reduced and whose heat-sensitive portion has good heat receiving characteristics.

1 is a side view showing the appearance of thermal alarm 100 according to Embodiment 1. FIG. 3 is a bottom view showing the appearance of the thermal alarm 100; FIG. FIG. 3 is an explanatory diagram showing the internal configuration of the housing 10 of the thermal alarm device 100; FIG. 4 is a sectional view showing a BB section of FIG. 3; FIG. 4 is a sectional view showing a CC section of FIG. 3; FIG. 3 is a sectional view showing the AA section of FIG. 2; FIG. 9 is an explanatory diagram showing the configuration inside a housing 310 of a thermal alarm 300 according to Embodiment 2; FIG. 8 is a sectional view showing a DD section of FIG. 7;

Embodiment 1.
FIG. 1 is a side view showing the appearance of a thermal alarm 100 according to Embodiment 1. FIG. FIG. 2 is a bottom view showing the appearance of the thermal alarm 100. FIG. The thermal alarm 100 is installed in a monitoring space such as a room of a house, for example, and monitors the ambient temperature. The thermal alarm 100 notifies a fire when the ambient temperature reaches or exceeds a certain temperature.

As shown in FIGS. 1 and 2, the thermal alarm 100 includes a base 20 attached to a ceiling 200, a main body 40, a cover 30 having a flow hole through which air flows, and a recess provided in the cover 30. a member 34; A housing 10 of the thermal alarm 100 is formed by the cover 30 and the main body 40 , and the housing 10 is detachably attached to the base 20 . The pushing member 34 is an inspection button that the operator presses when starting the operation test of the thermal alarm 100 . Hereinafter, the arrow X direction represents the width direction of the thermal alarm 100, the arrow Y direction represents the depth direction, and the arrow Z direction represents the height direction.

FIG. 3 is an explanatory diagram showing the configuration inside the housing 10 of the thermal alarm 100. As shown in FIG. As shown in FIG. 3, the thermal alarm 100 includes a speaker 70, a battery 80, and a middle plate 90 (see FIG. 4). there is The main body 40 includes a disk-shaped body portion 41 and a substrate 50 on which various electronic components such as the heat detection portions 60a and 60b are mounted. An airflow circulation space SP is formed between the body portion 41 and the cover 30 . Hereinafter, the heat detection units 60a and 60b will be referred to as the heat detection unit 60 when there is no particular need to distinguish between the heat detection units 60a and 60b. The heat detection section 60 is connected so that the heat sensitive section 61 is positioned on the floor surface side of the substrate 50 . Here, being positioned on the floor surface side means being positioned on the side opposite to the ceiling 200, and in FIG.

FIG. 4 is a sectional view showing the BB section of FIG. FIG. 5 is a sectional view showing the CC section of FIG. As shown in FIGS. 4 and 5 , the main body 40 is provided below the base 20 , and the battery 80 is housed between the base 20 and the main body portion 41 . A substrate 50 and a speaker 70 are provided on the lower surface 41 b side of the body portion 41 , and an intermediate plate 90 is arranged below the substrate 50 and the speaker 70 .

As shown in FIGS. 1 and 2, the cover 30 is formed in a cylindrical shape with a bottom, and includes a cylindrical cover side surface portion 31, a disk-shaped cover bottom surface portion 32, and a cover side surface portion 31 and a cover bottom surface portion 32. It has a slit part 33 provided between. The cover side portion 31 surrounds the outer periphery of the main body 40 . The cover bottom surface portion 32 is arranged to face the lower surface 41b of the main body portion 41 on which the substrate 50 and the like are provided.

Vertical holes 32a are formed through the left and right sides of the cover bottom portion 32, respectively. A plurality of protruding contact prevention portions 32c are provided on the inner peripheral wall 32b of each vertical hole 32a, and the vertical hole 32a is formed, for example, in the shape of a clover leaf. Each vertical hole 32a is located below each heat detection part 60a, 60b, and each heat detection part 60a, 60b is protected from contact with a finger, an instrument, or the like by a contact prevention part 32c. A vertical airflow flows into the circulation space SP through each vertical hole 32a. Here, the vertical airflow refers to an airflow flowing in a direction perpendicular to the surface of the ceiling 200 . A button hole 32 d is formed in the center of the cover bottom surface portion 32 for exposing the pushing member 34 from the cover bottom surface portion 32 .

The slit portion 33 includes a horizontal hole 33a that is open so as to extend in the circumferential direction of the cover 30, a plurality of main struts 33b that extend in the vertical direction (the arrow Z direction), and a plurality of main struts 33b that are provided between adjacent main struts 33b. It has a sub-post 33c and a ring-shaped partition member 33d that partitions the horizontal hole 33a. Each main support pillar 33b supports the cover bottom surface portion 32. As shown in FIG. Each sub-support 33c is thinner than the main support 33b and supports the partition member 33d together with the main support 33b. The horizontal hole 33a is partitioned into two stages by a ring-shaped partition member 33d. A horizontal airflow flows into the circulation space SP through the horizontal holes 33a. Also, the airflow in the circulation space SP flows out of the thermal alarm 100 through the horizontal hole 33a. Here, horizontal airflow refers to airflow flowing in a direction parallel to the surface of the ceiling 200 .

As shown in FIGS. 3 and 4, the main body portion 41 has a substrate installation portion 43 forming a space in which the substrate 50 is accommodated, and a battery accommodation portion 42 forming a space in which the battery 80 is accommodated. . The board installation portion 43 is provided, for example, in the central portion of the body portion 41 . The battery housing portion 42 is provided closer to the outer circumference of the main body portion 41 than the substrate setting portion 43 is. Specifically, the battery housing portion 42 is provided forward in the depth direction (arrow Y direction) and on the right side in the width direction (arrow X direction) with respect to the center O1 of the main body portion 41 . Here, the center O1 of the body portion 41 coincides with the center of the circulation space SP.

A rectangular substrate 50 with one corner cut out in an arc shape is accommodated in the substrate installation portion 43 so that the cutout portion 50a is located on the rear left side with respect to the center O1 of the main body portion 41 . The substrate installation portion 43 is a wall portion formed along the shape of the substrate 50 so as to protrude toward the cover bottom portion 32 , and accommodates the substrate 50 so that the edge of the substrate 50 faces the substrate installation portion 43 . be done.

A cylindrical battery 80 is accommodated in the battery accommodating portion 42 with the axial direction being the width direction (arrow X direction). The upper surface 41a side of the main body part 41 of the battery accommodating part 42 has a concave shape along the outer shape of the battery 80, so that the lower surface 41b side of the main body part 41 has a raised shape. The raised lower surface 41b faces the cover bottom surface portion 32 without a gap, thereby partitioning the circulation space SP.

A control circuit is provided on the board 50 , and operating power for the control circuit is supplied from a battery 80 . On the lower surface 50b of the substrate 50, a switch 51 for detecting that the push-in member 34 is pushed, a confirmation light 52 consisting of, for example, an LED or the like and turned on when a fire is detected, and a heat of the hot air flow are detected. A plurality of heat detectors 60a and 60b are mounted. As shown in FIGS. 4 and 5, the substrate 50 is formed with pin holes 50c and 50d for mounting the heat detectors 60a and 60b, respectively.

The control circuit receives the output value of each heat detector 60a, 60b and determines the ambient temperature based on the output value. The control circuit outputs a fire signal to the speaker 70 when the ambient temperature is determined to be equal to or higher than a certain temperature based on at least one of the heat detectors 60 . Note that the control circuit may be configured to output a fire signal to the speaker 70 when there is a temperature change equal to or greater than a set value in a short period of time.

As shown in FIGS. 3 and 5 , the speaker 70 has a circular shape and is installed on the lower surface 41 b of the main body 41 . The speaker 70 is arranged on the rear left side of the center O<b>1 of the main body 41 , and a part of the speaker 70 is located in the notch 50 a of the substrate 50 . That is, as shown in FIG. 3, the battery housing portion 42 is arranged on one side of the virtual line Lv passing through the center O1 of the main body portion 41, and the speaker 70 is placed on the virtual line Lv across the battery housing portion 42 and the center O1. are placed. Here, the imaginary line Lv is a line that passes through the center O1 of the main body portion 41 and connects the battery housing portion 42 and the speaker 70. It does not necessarily have to pass through the center of the battery housing portion 42 and the center of the speaker 70. do not have.

The speaker 70 includes a diaphragm 71 or the like that generates sound by vibration, and is electrically connected to the substrate 50 . When a fire signal is input from the control circuit of the substrate 50 to the speaker 70, the speaker 70 vibrates the diaphragm 71 to generate sound.

FIG. 6 is a cross-sectional view showing the AA cross section of FIG. The push-in member 34 is an inspection button operated during an operation test of the thermal alarm 100, and also functions as an indicator light when a fire occurs. The pushing member 34 is made of a translucent material such as acrylic resin, and has a button portion 34a exposed from the button hole 32d of the cover bottom portion 32 and a guide portion 34b extending toward the substrate 50 side. . The tip of the guide portion 34b is positioned directly below the switch 51 and the confirmation light 52 provided on the substrate 50. As shown in FIG. The position where the pushing member 34 is provided may be determined according to the position of the substrate 50 in the main body 40 . When the button portion 34a is pressed by an operator or the like during an operation test, the switch 51 is turned on by being pressed by the guide portion 34b, and an operation for checking the function of the thermal alarm 100 is started. On the other hand, when a fire is detected and the confirmation lamp 52 is turned on, the projection light of the confirmation lamp 52 is guided by the guide portion 34b and the button portion 34a emits light.

Each of the heat detectors 60 a and 60 b has a heat sensitive part 61 for detecting heat, a rod-shaped lead part 62 made of a lead wire, and a pin 63 provided at the base end of the lead part 62 . The heat sensitive part 61 is composed of, for example, a thermistor or the like whose resistance is changed by heat transferred from an airflow, and converts a temperature change into an electric signal and outputs the electric signal.

The heat sensitive portion 61 is attached to the tip portion of the lead portion 62, and the heat sensitive portion 61 and the lead portion 62 are integrally coated. By inserting the pins 63 of the heat detectors 60 a and 60 b into the pin holes 50 c and 50 d of the board 50 , the base ends of the lead parts 62 are connected to the board 50 and the heat sensitive parts 61 are connected to the board 50 . electrically connected to the control circuit; In other words, the heat detection units 60a and 60b are connected to the substrate 50 so as to be connected to the floor surface side of the substrate 50. As shown in FIG. Each lead portion 62 may be connected to the substrate 50 by soldering.

As shown in FIGS. 5 and 6 , the middle plate 90 covers the substrate 50 and the speaker 70 . A gap is provided between the intermediate plate 90 and the cover 30 . The intermediate plate 90 is provided facing a guide hole 92 through which the guide portion 34b of the pushing member 34 passes, two detection holes 91 provided on the left and right sides of the guide hole 92, and the diaphragm 71 of the speaker 70. A speaker hole 93 is provided. Each heat detecting portion 60 a , 60 b is passed through each detecting hole 91 . The speaker hole 93 is formed by a plurality of small holes radially provided from the center of the diaphragm 71 . Sound generated by the speaker 70 passes through the speaker hole 93 and is transmitted to the outside through the distribution space SP and the cover 30 .

As shown in FIG. 3, the two heat detectors 60a and 60b are arranged along the center line Lc so as to sandwich the center O1 of the main body 41 so that each heat detector 61 faces the outer circumference. Here, the center line Lc is a straight line passing through the center O1 of the main body 41, which is set separately from the virtual line Lv so as to avoid structures. In other words, each heat sensitive portion 61 of each heat detecting portion 60a, 60b is arranged at a position deviated from the virtual line Lv. Specifically, when the areas formed by dividing the circulation space SP into two by the imaginary line Lv are defined as a first area R1 and a second area R2, the heat sensitive part 61 of one heat detecting part 60a is located in the first area. The heat sensing portion 61 of the other heat sensing portion 60b is located in the second region R2. By arranging such a structure and each of the heat detection units 60a and 60b, areas where it is difficult for the airflow to blow through are collected on the diagonal of the circulation space SP, and a space where the airflow can easily pass is secured at a position away from the virtual line Lv. Then, the two heat sensitive parts 61 can detect the heat of the hot airflow in their respective regions.

Further, as shown in FIG. 6, each lead portion 62 of each heat detection portion 60a, 60b is attached at an angle to the substrate 50, and gradually approaches the cover bottom portion 32 from the base end to the tip. . The angle formed by the lower surface 50b of the substrate 50 and the lead portion 62 is hereinafter referred to as an inclination angle θ. Each lead portion 62 has a length such that the tip thereof is located outside the outer periphery of the substrate 50 .

The position of the heat sensitive portion 61 provided at the tip of the lead portion 62 will be described in detail. Each heat-sensitive portion 61 is arranged between the substrate 50 and the cover bottom portion 32 at a position facing the horizontal hole 33a in the height direction (arrow Z direction). Each heat-sensitive portion 61 is arranged on the outer peripheral side of the outer edge 50 e of the substrate 50 and positioned between the outer edge 50 e of the substrate 50 and the cover side portion 31 . In particular, as shown in FIGS. 3 and 4, the heat sensitive portion 61 of the heat detection portion 60b is provided so as to be positioned outside the battery housing portion 42 in the width direction (the direction of the arrow X), and the hot air flow F2 described later is provided. is easier to hit.

With such a configuration of the heat detection units 60a and 60b, it is possible to secure a certain distance between each heat sensing unit 61 and the main body 40, so that the heat of the air flow passing through the heat sensing unit 61 is absorbed by the main body 40. It is possible to suppress heat from being generated, and the heat sensing portions 61 can receive heat with high efficiency. In addition, since each heat sensitive portion 61 is closer to the cover 30 than the base end portion of the lead portion 62 and the two heat sensitive portions 61 are arranged on the center line Lc with the center O1 interposed therebetween, the inside of the cover 30 can be detected from any direction. Even when an air current flows in, there is no particular delay in detection. That is, the directivity can be lowered. Furthermore, since the airflow flowing in from the vertical holes 32a flows not only in the horizontal holes 33a but also in the spaces above the respective heat sensitive parts 61, the flow of the airflow is improved and the amount of airflow flowing in from the vertical holes 32a can be increased. can be done.

When each heat-sensitive portion 61 is arranged outside the outer circumference of the substrate 50, the inclination angle θ of the lead portion 62 may be 0°. Also in this case, since each heat sensitive portion 61 is separated from the substrate 50 and the main body portion 41 and a space is provided above each heat sensitive portion 61, good heat receiving characteristics can be obtained.

Based on FIG. 1, the flow of air currents during a fire will be described. When a fire breaks out in the monitored space, a vertical airflow is generated from the fire source toward the ceiling 200, and after reaching the ceiling 200, the direction of the airflow becomes parallel to the ceiling 200 and flows along the ceiling 200 as a horizontal airflow. If the origin of the fire is directly below the thermal alarm 100 , the vertical airflow reaches the cover bottom portion 32 . Also, when the fire source is not directly below the thermal alarm 100, the vertical airflow rising from the fire source all reaches the ceiling 200, flows as a horizontal airflow along the ceiling 200, and reaches the thermal alarm 100. reach.

Next, with reference to FIG. 3, the flow of horizontal airflow reaching the slit portion 33 of the thermal alarm 100 will be described. The position and direction of the horizontal airflow are different depending on the position of the origin of the fire. First, the case where the fire source is on the front side of the thermal alarm 100 will be described using the hot airflows F1 to F3.

The hot airflow F1 that has reached the slit portion 33 at the front center position flows into the housing 10 through the horizontal hole 33a, flows along the battery housing portion 42, and conducts heat to the heat detection portion 60a, thereby flowing horizontally. It flows out of the housing 10 through the hole 33a. The hot airflow F2, which reaches the slit portion 33 at a position on the right side of the hot airflow F1, flows into the housing 10 from the horizontal hole 33a, advances along the right side surface 42a of the battery housing portion 42, and travels outside the right side surface 42a. The heat is transmitted to the heat sensitive portion 61 of the heat detecting portion 60b located at , and flows out from the horizontal hole 33a. The hot airflow F3 that reaches the slit portion 33 at the front left position flows into the housing 10 through the horizontal hole 33a and blows through the space on the left side of the battery housing portion 42 . At this time, since the hot airflow F3 flows into the housing 10 and immediately passes through the heat sensing portion 61 of the heat detection portion 60a, heat is efficiently transferred from the hot airflow F3 to the heat detection portion 60a.

In this way, even when there is a structure such as the battery containing portion 42, the hot airflow F2 passes through the heat detection portion 60b, and the hot airflow F1 and the hot airflow F3 pass through the heat detection portion 60a. Therefore, if a fire source exists in front of the thermal alarm 100, the heat is quickly detected in at least one of the two heat detection units 60a and 60b, and the thermal alarm 100 notifies the fire without delay. can be done.

For example, hot air flowing in a direction such as the hot air flow F3 is effective against the heat detecting portion 60a, but is less likely to hit the heat detecting portion 60b due to the presence of the battery containing portion 42. FIG. However, the heat detectors 60a and 60b are arranged symmetrically from the center O1 and are arranged on the outer peripheral side so as to avoid the structure. At least one of them can efficiently detect heat.

Next, the case where the origin of fire is behind the thermal alarm 100 will be described using the hot airflows F4 to F6. The hot airflow F4 that reaches the slit portion 33 on the rear left side flows into the housing 10 through the horizontal hole 33a and passes through the gap between the middle plate 90 arranged below the speaker 70 and the cover bottom portion 32. . At this time, the hot airflow F4 bends to the left side of the speaker 70, which has a wide space, transfers heat to the heat sensitive portion 61 of the heat detecting portion 60a, and flows out from the horizontal hole 33a. The hot airflow F5 that reaches the slit portion 33 at the rear center position is not between the speaker 70 and the cover bottom portion 32, which is narrow, but between the intermediate plate 90 and the cover bottom portion 32, which is wide, or in the wider space on the right side. It bends into space, conducts heat to the heat detection part 60b, and flows out of the housing 10. - 特許庁This is also because such a flow is affected by the presence of the battery containing portion 42 on the traveling direction side. The hot airflow F6 that reaches the slit portion 33 on the rear right side flows into the housing 10 through the horizontal hole 33a and blows through the space on the right side of the speaker 70 . At this time, the hot airflow F6 flows into the housing 10 and immediately passes through the heat sensing portion 61 of the heat detection portion 60b, so heat is efficiently transferred from the hot airflow F6 to the heat detection portion 60b.

Thus, even if there is a structure such as the speaker 70, the hot airflow F4 passes through the heat detection section 60a, and the hot airflow F5 and the hot airflow F6 pass through the heat detection section 60b. Therefore, even if there is a fire source behind the thermal alarm 100, the heat is quickly detected by at least one of the two heat detection units 60a and 60b, so that the thermal alarm 100 can be operated without delay. A fire can be reported.

Also, when the fire source is on the left side of the thermal alarm 100, the horizontal airflow reaches the left side of the slit portion 33 and flows into the housing 10 from the horizontal hole 33a, and immediately after the flow, the heat detection portion Transfer heat to 60a. Similarly, when the fire source is on the right side of the thermal alarm 100, the horizontal airflow reaches the right side of the slit portion 33 and flows into the housing 10 from the horizontal hole 33a, and the heat is detected immediately after the flow. Heat is transferred to the portion 60b. Thus, the thermal alarm 100 can quickly detect a fire regardless of the location of the fire origin.

Next, with reference to FIG. 6, the flow of the vertical air current when the origin of fire is directly below the thermal alarm 100 will be described. A hot airflow F8 shown in FIG. 6 represents a vertical airflow that reaches the vertical hole 32a of the cover bottom portion 32 when the origin of the fire is directly below the thermal alarm 100. FIG. The hot airflow F8 flows into the housing 10 from each vertical hole 32a, and the hot airflow F8 that has flowed in directly strikes each heat sensitive part 61, and heat is transmitted. After that, part F8a of the hot airflow F8 flows out of the housing 10 through the horizontal hole 33a. The remaining portion F8b of the hot airflow F8 flows into the space provided between the heat sensitive portion 61 and the main body portion 41, hits the lower surface 41b of the main body portion 41, is guided to the slit portion 33, and flows out from the horizontal hole 33a. In this manner, the hot airflow F8 can travel further inside after passing through the heat-sensitive portion 61, thereby promoting the inflow of the hot airflow from each of the vertical holes 32a. Further, since the heat-sensitive portion 61 and the body portion 41 are separated from each other, the body portion 41 is less likely to lose heat from the hot air flow, and the heat-sensitive portion 61 easily receives heat.

On the other hand, the hot air that reaches the outer side of each vertical hole 32a flows along the cover bottom portion 32, part of which flows into the cover 30 through the vertical holes 32a, It flows to the ceiling 200 through the outer surface.

As described above, in Embodiment 1, the heat detection units 60 a and 60 b are connected to the substrate 50 so that the heat sensing unit 61 is positioned closer to the outer periphery of the main body 41 than the position connected to the substrate 50 . The two heat-sensitive parts 61 are arranged on a line segment passing through the center O1 of the body part 41 so as to sandwich the center O1. As a result, even when the heat detection units 60a and 60b are provided inside the cover 30, the heat of the hot airflow is absorbed by the main body 41, the substrate 50, and the like, and the hot airflow reaches one of the heat sensing units 61 before the temperature drops. can pass. Also, the hot airflow can be applied to the heat sensitive portion 61 without being obstructed by the lead portion 62 of the heat detecting portion 60 . Therefore, the protector can be omitted to reduce the thickness of the thermal alarm 100, and good heat receiving characteristics can be obtained.

In general, the type and arrangement of structures housed in the housing 10 differ depending on the model and the like. Therefore, simply installing the heat detection unit in the cover 30 increases the directivity depending on the arrangement of the structure. On the other hand, in the thermal alarm 100, by devising the arrangement of the two heat-sensitive parts 61, it is possible to reduce the bias in sensitivity caused by the location of the origin of the fire and to obtain good heat-receiving characteristics.

Moreover, the heat sensitive part 61 of each of the heat detecting parts 60a and 60b is arranged between the main body part 41 and the cover bottom face part 32 facing the main body part 41, and the heat detecting part 60 protrudes toward the floor surface side of the substrate. It is designed to In other words, the heat detection unit 60 provided on the substrate inside the housing 10 is provided so as to protrude toward the cover side on the floor side rather than the main body side on the ceiling side. As a result, the heat-sensitive portion 61 can be separated from the body portion 41 and the substrate 50 and brought closer to the horizontal hole 33a and the vertical hole 32a, which are flow holes. Therefore, the hot airflow that has flowed into the circulation space SP can be passed through the heat sensitive portion 61 quickly, so that the heat detecting portions 60a and 60b can quickly and efficiently detect the heat of the airflow.

Also, the heat sensitive portions 61 of the heat detecting portions 60 a and 60 b are arranged outside the outer edge 50 e of the substrate 50 . As a result, there is no substrate 50 above the heat-sensitive portion 61 and a space is provided between the heat-sensitive portion 61 and the main body portion 41 . can be ensured. Furthermore, when the vertical holes 32a are provided, the airflow that has passed through the heat-sensitive portion 61 further enters to the upper part, so that the airflow can easily pass through the housing 10, and the outflow and inflow of the hot airflow can be promoted. can. Therefore, compared to the case where the substrate 50 is also provided above the heat sensitive portion 61, the amount of hot air flow passing through the heat sensitive portion 61 is increased, and good heat receiving characteristics can be obtained.

Embodiment 2.
FIG. 7 is an explanatory diagram showing the configuration inside the housing 310 of the thermal alarm 300 according to the second embodiment. FIG. 8 is a sectional view showing a DD section of FIG. FIG. 8 depicts body 340 with midplate 390 attached. Embodiment 2 differs from Embodiment 1 in the arrangement of structures, the shape of main body 340, the shape of intermediate plate 390, the shape of substrate 350, and the arrangement of heat detectors 60a and 60b. Hereinafter, in the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

The battery housing portion 342 is provided so as to extend forward from the center O1 of the main body portion 341, and the battery 80 is housed in the battery housing portion 342 with the axial direction being the depth direction (arrow Y direction). The speaker 70 is arranged on the left side of the battery housing portion 342 . The substrate 350 is arranged below the main body portion 341 so as to extend over the rear side of the speaker 70 and the battery housing portion 342 and the right side of the battery housing portion 342 .

The intermediate plate 390 is provided below the main body portion 341 so as to cover the substrate 350 and the speaker 70 . The right side portion of the intermediate plate 390 extends forward along the right side surface 342 a of the battery housing portion 342 to the outer periphery of the main body portion 341 . A circulation space SP is formed between the main body portion 341 provided with the intermediate plate 390 and the cover 30 . By providing the middle plate 390, the unevenness of the circulation space SP can be reduced and the resistance can be reduced.

Further, the intermediate plate 390 is formed with a guide hole 392 through which the guide portion 34b of the pushing member 34 is passed, two detection holes 391, and a speaker hole 393 provided facing the diaphragm 71 of the speaker 70. ing. The two detection holes 391 are provided at positions facing the base ends of the two heat detection parts 60 a and 60 b installed on the left and right sides of the substrate 350 .

The base ends of the lead portions 62 are soldered to the substrate 350 to electrically connect and fix the heat detecting portions 60 a and 60 b to the substrate 50 . The lead portion 62 is inserted into the detection hole 391 of the intermediate plate 390 , and the heat sensitive portion 61 is arranged between the intermediate plate 390 and the cover bottom portion 32 . The heat detection units 60 are provided on the left and right sides of a substrate 350 arranged behind the center O1 of the body portion 341, and each lead portion 62 is fixed to the substrate 350 so as to extend forward and to the outer peripheral side, The two heat-sensitive parts 61 are arranged on the center line Lc with the center O1 of the body part 41 interposed therebetween.

Further, the shape of the substrate 350 is formed such that the outer circumference is recessed at the position of the heat sensitive portion 61 . Thus, also in the second embodiment, each heat-sensitive portion 61 is arranged to be located between the outer edge 350 e of the substrate 350 and the cover side portion 31 on the outer peripheral side of the outer edge 350 e of the substrate 350 .

Also, the length Dd of the lead portion 62 in the heat detection portion 60 is shorter than the diameter Ds of the speaker 70 . The heat-sensitive portion 61 is positioned on the outer peripheral side by 80% or more of the diameter of the body portion 341 . By arranging the heat-sensitive portion 61 near the slit portion 33, the heat-sensitive portion 61 can easily receive heat. making it easy. In FIG. 7, the lead portion 62 of the heat detecting portion 60 is provided so as to contact the speaker 70, but if the heat sensitive portion 61 is located on the diameter of the main body, how should the lead portion 62 be arranged? You may make it provide.

Next, the flow of the horizontal airflow reaching the thermal alarm 300 will be described with reference to FIG. When the fire source is on the front side of the thermal alarm 300, the hot air flow F12 that reaches the slit portion 33 at the left front position flows into the housing 310 through the horizontal hole 33a, and reaches the heat detection portion 60a. , and flows out of the housing 310 through the horizontal hole 33a. The hot airflow F15 that reaches the slit portion 33 at the front right position flows into the housing 310 through the horizontal hole 33a, transfers heat to the heat detection portion 60b, and flows out of the housing 310 through the horizontal hole 33a. leak.

When the fire source is on the rear side of the thermal alarm 300, the hot airflow F13 that reaches the slit portion 33 at the rear left position flows into the housing 310 through the horizontal hole 33a and reaches the heat detection portion 60a. , and flows out of the housing 310 through the horizontal hole 33a. The hot airflow F16 that reaches the slit portion 33 at the rear right position flows into the housing 310 through the horizontal hole 33a, transfers heat to the heat detecting portion 60b, and flows out of the housing 310 through the horizontal hole 33a. leak.

Here, the hot airflows F12 and F15 flowing in from the front and the hot airflows F13 and F16 flowing in from the rear have substantially the same distance from entering the housing 310 to reaching the heat-sensitive portion 61 . For example, if the line connecting the two heat-sensitive parts 61 does not pass through the center O1 and is located behind, the fire will flow into the housing 310 before reaching the heat-sensitive part 61 when the fire origin is in the front compared to when it is in the rear. Detection may be delayed due to longer distances to reach. On the other hand, in the configuration in which the two heat-sensitive parts 61 are arranged on the center line Lc with the center O1 interposed therebetween, as in the thermal alarm 300, heat is generated depending on whether the fire origin is in front or in the rear. There is no particular difference in the time until detection.

When the fire source is on the left side of the thermal alarm 300, the hot airflow F11 that reaches the slit portion 33 at the left side flows into the housing 310 from the horizontal hole 33a and immediately passes through the heat detection portion 60a. , hits the battery accommodating portion 342, bends rearward, and flows out from the horizontal hole 33a. The hot airflow F11 does not pass through the heat sensitive part 61 of the heat detection part 60b, but passes through the heat detection part 60a immediately after flowing into the housing 310, so heat is efficiently transferred from the hot airflow F11 to the heat detection part 60a.

When the fire source is on the right side of the thermal alarm 300, the hot airflow F14 hits the battery housing portion 342 and bends, so it does not pass through the heat sensing portion 61 of the heat detection portion 60a, but the heat is detected as soon as it flows into the housing 310. Since it passes through the portion 60b, the heat detection portion 60b can efficiently detect the heat from the hot airflow F14.

Also, when the hot airflow F17 flows from the obliquely front right side of the main body toward the center, the flow is blocked by the battery housing portion 342, so heat is less likely to be transmitted to the heat detection portion 60a. However, since the heat detection part 60b is located symmetrically with respect to the heat detection part 60a with the center O1 interposed therebetween, the heat can be efficiently detected by the heat detection part 60b. Further, when the hot airflow F18 flows toward the center from the obliquely rear left side, heat can be efficiently detected because the heat detection part 60a exists near the horizontal hole 33a. Thus, by combining the two heat detection units 60a and 60b, it is possible to detect hot airflow from any direction of 360°.

As described above, also in the second embodiment, the heat detection units 60a and 60b are connected to the substrate 50 so that the heat sensing unit 61 is positioned closer to the outer periphery of the main body unit 41 than the position connected to the substrate 50. The two heat sensitive parts 61 are arranged on the center line Lc so as to sandwich the center O1. As a result, in the thermal alarm 300 of the second embodiment, as in the case of the first embodiment, it is possible to obtain good heat receiving characteristics while reducing the thickness.

It should be noted that the embodiments of the present invention are not limited to the above embodiments, and various modifications can be made. For example, the number of heat detection units 60 may be three or more. Also, the first structure and the second structure are not limited to the battery housing portion 42 and the speaker 70 . For example, the structure that occupies the largest volume in the space formed between the main body 40 and the cover 30 is the first structure, and the structure that occupies the next largest volume after the first structure is the second structure. can be defined as objects.

Next, the vertical hole will be explained. Since the heat-sensitive part 61 above the vertical hole 32a can be seen from the front as shown in FIG. etc.). However, the vertical holes 32a may not necessarily be provided if good heat receiving characteristics can be obtained. Alternatively, although the embodiment has been described in which the vertical holes 32a are provided in the lower portions of both the heat sensing portions 61, for example, in a heat alarm using two heat sensing portions 60, the heat sensing portion 60a of one of the heat sensing portions 60a may Only the portion 61 may be provided with the vertical hole 32a. In other words, the portion of the cover facing the heat sensitive portion 61 of the other heat detecting portion 60b may be closed without forming a vertical hole. By doing so, the heat sensing portion 61 of the heat detecting portion 60b on the side without the vertical hole is not visible from the outside, so there is no restriction on the design as described above, and the installation position of the heat detecting portion 60 on the substrate 50 can be determined. You can design freely. That is, since there is no vertical hole 32a, the position of the heat sensing part 61 of the heat detection part 60b does not have to be symmetrical as long as it is on the diameter of the body part 40. For example, the heat detection part facing the vertical hole 32a The heat receiving efficiency may be enhanced by locating the heat sensitive portion 60a further on the outer peripheral side of the main body portion 41 with respect to the heat sensitive portion 61 of 60a.

Also, the shape of the vertical hole 32a is not limited to the shape shown in FIG. 2, and may be circular or slit-shaped. When the vertical hole has a slit shape, its length is about the same as the length Dd of the lead portion of the heat detecting portion 60, and its width can be about 5 mm to prevent fingers from entering. Considering the shape and size of the hole, the vertical hole may have any shape as long as it allows a sufficient vertical airflow to flow into the circulation space SP and does not allow the heat-sensitive part to be easily touched with a finger or the like. , and the number can be freely determined according to the number of the heat detection units 60 .

Here, the position where the heat detection unit 60 is provided will be mentioned. The heat sensitive portion 61 formed at the tip of the heat detecting portion 60 is desirably provided on the outer peripheral side of the main body 40 as close to the circulation hole as possible. This is because the closer to the outer periphery of the main body 40, the higher the temperature of the hot air flow, and the better the heat receiving efficiency. As described above, since there are horizontal and vertical hot air currents entering the main body 40, the heat sensitive portion 61 may be positioned at approximately the same distance from both the horizontal hole 33a and the vertical hole 32a. good.

In the above embodiment, the thermal fire alarm equipped with the battery 80 and the speaker 70 has been described, but the present invention can be applied to a thermal sensor that does not have the battery 80 and the speaker 70. You may do so.

10, 310 housing, 20 base, 30 cover, 31 cover side portion, 32 cover bottom portion, 32a vertical hole, 32b inner peripheral wall, 32c contact prevention portion, 32d button hole, 33 slit portion, 33a horizontal hole, 33b main support column , 33c sub-support 33d partition member 34 pushing member 34a button portion 34b guide portion 40, 340 main body 41, 341 main body portion 41a main body upper surface 41b main body lower surface 42, 342 battery housing portion 42a, 342a Right side 43 Substrate installation part 50, 350 Substrate 50a Notch 50b Lower surface (of substrate) 50c Pin hole 50d Pin hole 50e, 350e Outer edge 51 Switch 52 Confirmation light 60, 60a, 60b Heat detection part 61 Heat sensitive part 62 Lead part 63 Pin 70 Speaker 71 Diaphragm 80 Battery 90, 390 Middle plate 91, 391 Detection hole 92, 392 Guide hole 93, 393 Speaker hole 100 , 300 thermal alarm, 200 ceiling, Dd lead length, Ds speaker diameter, F1, F2, F3, F4, F5, F6, F7, F8, F11, F12, F13, F14, F15, F16, F17, F18 hot air flow, Lc center line, Lv imaginary line, O1 center (of main body), R1 first region, R2 second region, SP circulation space, θ angle of inclination.

Claims (2)

a main body;
a cover having a circulation hole and forming a circulation space between itself and the main body;
a substrate provided on the main body so as to face the cover and having a circuit;
two heat detection parts having heat sensitive parts at their ends and detecting the heat of the air flow that has flowed into the circulation space through the circulation hole and are electrically connected to the substrate;
the cover has a bottom surface facing the main body on which the substrate is provided;
The bottom surface is provided with a vertical hole through which a vertical airflow flows,
Each of the heat detectors is arranged so that the heat sensitive part is positioned closer to the outer periphery of the main body than the position connected to the substrate, and the heat sensitive part is positioned closer to the bottom surface of the cover than the substrate. connected to the board,
The body portion is provided with a structure accommodating portion that has a shape that rises toward the bottom surface of the cover and that forms a space for accommodating an elongated structure on the side opposite to the bottom surface. ,
When the main body is viewed from the bottom side,
The heat sensitive parts of the two heat detection parts are arranged on a line segment passing through the center of the main body so as to sandwich the center of the main body,
The structure housing portion extends from the center side of the main body portion toward the outer peripheral side in a direction orthogonal to the line segment passing through the center of the main body portion,
A thermal alarm, wherein the heat sensitive part of each heat detection part is arranged outside an outer edge of the substrate. A plurality of vertical holes are provided in the bottom surface of the cover,
2. The thermal alarm according to claim 1, wherein the heat sensing part of each heat detection part is arranged to face each vertical hole.

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