JP3949016B2 - Heating device such as water tank - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an improvement in a heating apparatus that is charged into a bucket or a water tank to heat the internal water to a predetermined temperature and maintain the water temperature.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, for example, in a water tank for appreciating tropical fish and the like, a heating device for heating and maintaining the temperature in the water tank at a constant temperature has been used. This heating device includes a heater that generates heat when energized, a switch element that supplies and shuts off power to the heater, a temperature detection sensor, and a temperature control circuit, and supplies power to the heater when the water temperature falls below a set temperature. The water in the tank is heated, and when the water in the tank reaches the set temperature, the switch element is turned off to stop the power supply to the heater, and this is repeated until the temperature of the water in the tank reaches a predetermined value. Hold at temperature.
[0003]
[Problems to be solved by the invention]
However, in the above heating device, such as water leakage or water tank overturning, or if the heater is out of the water tank by mistake, it will become empty and the heater will rise abnormally, causing a fire, etc. There is a risk of a very dangerous situation. For this reason, a temperature fuse is provided in the circuit, and when the temperature rises abnormally, the temperature fuse is blown to cut off the power, but once the temperature fuse blows, the structure of the heating device However, since the replacement cannot be performed, there is a problem that the entire apparatus must be discarded.
[0004]
On the other hand, although a heating device such as a water tank configured to detect an abnormal temperature of the heater that has reached a high temperature and cut off the power supply to the heater when the heating device is in an empty state has been developed, When this abnormal temperature is detected, the heater generates heat until it reaches a high temperature.
[0005]
The present invention has been made in view of the above problems, and when the heater is in the air by utilizing the change in the refractive index of light in the air and in the water, the energization to the heater is completely cut off, An object of the present invention is to provide a heating device such as a water tank that can be used safely by energizing a heater when it is in water.
[0006]
[Means for Solving the Problems]
In order to achieve the above-mentioned object, a heating device such as a water tank according to the present invention includes a cylindrical heater main body having a translucent structure in which a heater is internally provided, and a heater inside the heater main body. When the heater body is in the air, it is reflected toward the inside of the heater body on the surface of the heater body, while a light source that passes through the heater body when the heater body is in water and a heater body are disposed in the heater body. A light-receiving body that receives the reflected light, and a switch that turns off the heater when the light-receiving body receives the reflected light, and turns on the heater when the incident light is not transmitted through the heater body. It consists of a circuit.
[0007]
In the heating device such as a water tank configured as described above, the invention according to claim 2 is the first light receiving body that always directly receives light from the light source as the light receiving body, and the reflection when entering the heater body from the light source. And a second light receiving body for receiving light.
[0008]
Further, in the invention according to claim 1 or 2, the invention according to claim 3 is a circuit configuration of the apparatus, and an oscillation circuit that generates an electric signal by supplying a DC voltage from a power supply circuit, and A light source composed of a light emitting element driven by a signal from an oscillation circuit, a first light receiver composed of a phototransistor that directly receives light emitted from the light source, and a phototransistor that receives reflected light from the light source to the surface of the heater body. The second light receiving body comprising the above, the switch circuit for energizing and de-energizing the heater, and the signals from the first and second light receiving bodies are compared, and the first light receiving body receives the first light. 2 When a light receiving body is not receiving light, a signal is sent to the switch circuit to energize the heater. When the first and second light receiving bodies are both receiving light or not receiving light, the switch circuit is heated. Characterized in that it is constituted by a comparator circuit which generates a signal to de-energized.
[0009]
In the third aspect of the present invention, the fourth aspect of the present invention provides a rectangular wave input signal from the first and second light receivers between the first and second light receivers and the comparison circuit. The first and second Schmitt circuits that perform waveform shaping and the exclusive OR that detects the difference between the input signals from the first and second Schmitt circuits and inputs to the comparison circuit are connected to the first and second Schmitt circuits. The comparison circuit is set so that the heater is deenergized when the input signals from the second Schmitt circuit are the same.
[0010]
According to a fifth aspect of the present invention, in the first to fourth aspects of the invention, the heater body having translucency is a glass tube, and a transparent composite is partially formed in the heater body. The resin is filled, and the light source and the first and second light receivers are embedded in the filled synthetic resin.
[0011]
[Action]
When a circuit in the heater body is energized by connection to a power source such as an outlet, a light source disposed in the heater body emits light and irradiates the inner surface of the heater body with a predetermined incident angle. At this time, the heater body is made of glass, and the angle at which the light from the light source enters the heater body is less than the critical angle that causes total reflection at the interface between the heater body and air when the heater body is in the air. If the heater body is in water and the heater body is in water, the light from the light source is transmitted through the heater body when the heater body is in water. Although it does not enter the photoreceptor, when the water tank becomes empty due to water leakage or falling, incident light from the light source is reflected at the interface between the heater body and air and enters the photoreceptor.
[0012]
This photoreceptor is connected to a comparison circuit, which detects whether the photoreceptor is receiving light from the light source. When the photoreceptor is not receiving light, the switch circuit is energized to the heater. The heater is energized so that the heater can be energized to heat and hold the water in the water tank to a predetermined temperature, while when the photoreceptor receives light, the switch circuit is energized from the comparison circuit to the heater. A signal to shut off is issued to stop the operation of the heater.
[0013]
In such an operation of the heating device, when the light source does not emit light due to a failure or the like, the light is not incident on the photoreceptor, so the heater body is disposed in water even in the air. The heater is energized, the heater is energized, and it may rise abnormally and cause a fire. Therefore, as the light receiver, the light receiver that always directly receives the light from the light source and the light receiver that receives the reflected light of the light radiated from the light source to the inner surface of the heater main body as the first and second light receivers, respectively. It is arranged to detect whether the heater body is energized by the first photoreceptor, and at the same time, detect whether the heater body is in the air or underwater by the second photoreceptor. It is desirable to keep it.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a structure of a heating apparatus that heats water in a water tank to a predetermined temperature by introducing it into a bucket or water tank (hereinafter referred to as a water tank). A heater HR made of nichrome wire is arranged in one half part of a bottomed cylindrical heater body 1 made of a tube, while a water temperature sensing element made of a negative characteristic resistance element whose resistance value decreases when the temperature rises in the other half part. An NTC and a printed circuit board 4 in which a circuit fuse 2 and a temperature fuse 3 that melts and cuts off electric power when an abnormal temperature is reached are integrated, and light is emitted into the other end of the heater body 1. A light source LED composed of a diode (light emitting element), a first light receiver PHT1 that directly receives light (infrared rays) from the light source LED, and the heater body 1 in the air (in the air) The light is reflected off the surface of the glass tube A second photoreceptor PHT2 that receives the reflected light is disposed.
[0015]
These first and second photoreceptors PHT1 and PHT2 are formed of a phototransistor or a photodiode, which is a switch element that conducts current when receiving light, and the first photoreceptor PHT1 is formed from the light source LED in the vicinity of the light source LED. As shown in FIGS. 2 and 3, the second photoreceptor PHT2 is shielded from the light source LED by the shielding plate 5 and from the light source LED. Is disposed at a position for receiving the reflected light. The shielding plate 5 has a tip end surface in close contact with a part of the inner peripheral surface of the heater body 1 and is configured to irradiate light rays from the light source LED with a predetermined incident angle toward the glass surface of the contact portion. is doing.
[0016]
The incident angle of the light beam from the light source LED to the glass surface of the heater body 1 is such that when the heater body 1 is in the air, when the light beam is incident on the heater body 1 (glass tube), the surface of the heater body and the air The incident angle is less than the critical angle at which refraction occurs at the boundary surface with respect to the total reflection, and is set to an angle at which the light beam passes through the heater body 1 when the heater body 1 is in water. The second light receiving body PHT2 is disposed at a symmetrical position with respect to the light source LED, that is, a position for receiving the reflected light, with the shielding plate 5 as the center.
[0017]
Light is present when air is present between the light source that emits infrared light and the inner surface of the heater body 1 (glass tube) or between the first and second photoreceptors PHT1 and PHT2 and the inner surface of the heater body 1 (glass tube). Is reflected on the inner surface side of the heater body 1 without passing through the inside of the glass tube, so that the light source LED and the first and second light receivers PHT1 and PHT2 are in the other end of the heater body 1 together with the shielding plate 5. The outer peripheral surface is embedded in the wall 6 made of a transparent high-density synthetic resin that is integrally fixed to the inner surface of the heater body 1 in the above-described arrangement state.
[0018]
Therefore, the irradiation light (infrared rays) from the light source LED passes from the wall body 6 made of this transparent synthetic resin through the thick part of the glass tube forming the heater body 1 to the surface of the heater body 1. When the heater main body 1 is in the air, the heater main body 1 is reflected from the surface of the heater main body 1 without returning into the low-density air and returns to the synthetic resin wall body 6 again. When reaching the second photoreceptor PHT2 and the heater body 1 is in water, the density of water is higher than that of air, so that the light from the light source LED does not reflect on the surface of the heater body 1 and is predetermined in the water. And the second receptive body PHT2 is not reached.
[0019]
When the heater main body 1 is in the air, the reflected light of the light from the light source LED is received by the second light receiving body PHT2, and a signal for receiving this light is transmitted. When the heater HR is deenergized and the heater body 1 is in the water, the light from the light source LED travels in the water without being reflected, so that the second light receiver PHT2 receives the light. In response to this signal, the switch circuit PSW is operated so that the heater HR is energized.
[0020]
If the light emitted from the light source LED is visible light, the first and second photoreceptors PHT1 and PHT2 malfunction due to daily light, so that infrared rays are used as described above. Is made to emit light intermittently at a certain period, and the first and second photoreceptors PHT1 and PHT2 react only with the signal of the intermittent period, thereby distinguishing it from the naturally occurring light and constructing a reliable device ing. Further, an annular cover 7 that covers the first and second photoreceptors PHT1 and PHT2 is attached to the outer peripheral surface of the other end of the heater body 1, and natural light is blocked by the cover 7 so that the first and second light sources are covered. The photoreceptors PHT1 and PHT2 do not receive natural light. As shown in FIG. 3, the cover 7 is fixed to the heater body 1 through spacer pieces 8 disposed at several places on the outer peripheral surface of the other end of the heater body 1. In the water tank in the gap with the surface, air is present in the air, and the light from the light source LED is refracted as described above.
[0021]
The heater HR provided in one half of the heater body 1 has an abnormally high temperature due to the fact that the nichrome wire is disposed on both sides of the mica plate and buried with magnesia sand, etc. The temperature fuse 3 that cuts off the current when it is turned on is the same as the conventional heating device in that it is disposed in the heater body 1, and a partition rubber 9 is provided between the heater HR and the printed circuit board 4. Silicone resin is barreled in the other half of the heater body 1 on the printed circuit board 4 side.
[0022]
Further, the power cord 11 connected to the circuit on the printed circuit board is pulled out from the rubber cap 10 whose opening end provided on the other end side of the heater body 1 is sealed in a watertight state. Plug 12 is connected. In this case, a fixed temperature type heating device without a temperature setting unit is configured, but a variable temperature setting type heating device with a temperature setting unit (not shown) provided in the middle of the power cord 11 is used. It may be configured. In the case of the above-mentioned fixed temperature type heating device, a switch circuit for energizing and shutting off the heater HR is provided in the heater body 1, but in this set temperature variable type heating device, the switch circuit is a temperature setting section or a heater body. It may be incorporated in either of the above.
[0023]
Next, a specific example of an electric circuit that detects when the heater body 1 is in water and turns on the heater HR, and detects this when in the air (in the air) to turn off the heater HR. A typical configuration will be described with reference to FIG.
[0024]
In this figure, this electric circuit includes a power supply circuit PS that generates a DC voltage for operating the circuit, and an oscillation circuit that is connected to the power supply circuit PS and generates an alternating current (electrical signal) by supplying a DC voltage from the power supply circuit PS. OSC, an excitation amplifier circuit EXT that is connected to the output side of the oscillation circuit OSC to increase the power of the electric signal, the light source LED composed of a light emitting element driven by a signal from the oscillation circuit OSC, and the light source LED On the output side of the first and second photoreceptors PHT1 and PHT2, and the second photoreceptor PHT2 that receives reflected light from the light source LED. The first and second Schmitt circuits ST1 and ST2 for connecting and respectively shaping the input signals from the first and second photoreceptors PHT1 and PHT2, and the input signals from the first and second Schmitt circuits ST1 and ST2 Detect whether the two are different or the same The exclusive OR EXOR input to the voltage comparison circuit CMP2 through the circuit RC and the output of the voltage comparison circuit CMP2 are connected to the output side of the voltage comparison circuit CMP2. Power switch circuit PSW.
[0025]
Further, the water temperature sensing element NTC provided in the heater body 1 and the reference voltage Vref corresponding to the set temperature of the temperature setting unit are connected to the power switch circuit PSW via the voltage comparison circuit CMP1 different from the voltage comparison circuit CMP2. Connected to. The temperature setting unit is configured to set the temperature by changing the resistance value by rotating the knob.
[0026]
The operation of the heating apparatus having the electric circuit configured as described above will be described. When the plug 12 of the power cord 11 is connected to the power supply, a DC voltage necessary for circuit operation is supplied by the power supply circuit PS, a signal having a fixed period is generated in the oscillation circuit OSC, and this signal is driven by the excitation amplifier circuit EXT. It is strengthened to drive the light source LED, and this light source LED continues to emit infrared light at a constant cycle.
[0027]
When the light source LED emits light, the first light receiver PHT1 directly irradiates the infrared light without being shielded, whereas the second light receiver PHT2 is shielded by the shielding plate 5 because the infrared light is blocked. Then, the light enters the inner surface of the glass tube forming the heater body 1 with which the front end surface of the shielding plate 5 is in contact at a predetermined incident angle. At this time, if the heater main body 1 is in the water in the water tank, the density of water is higher than that of air, so that the infrared rays that have entered the glass tube (heater main body 1) in the thickness direction and reached the surface of the heater main body 1 While being refracted as it is, it is irradiated into the water and is not received by the second photoreceptor PHT2, but if the heater body 1 is in the air, the infrared rays that have reached the surface of the glass tube (heater body 1) will enter the low-density air. Instead, the light is reflected on the surface of the heater body 1 and passes over the shielding plate 5 to reach the second light receiving member PHT2, and is received by the second light receiving member PHT2.
[0028]
Since the first and second photoreceptors PHT1 and PHT2 are composed of phototransistors, when receiving infrared rays, they generate a rectangular wave electric signal, and these electric signals are shaped by the Schmitt circuits ST1 and ST2, and the same. A signal of the same rectangular wave in the cycle is output, and a high level “1” signal is output to the exclusive OR EXOR side. On the other hand, when the first and second photoreceptors PHT1 and PHT2 do not receive light, a low level “0” signal is output.
[0029]
The exclusive OR EXOR is used when the two input signals are the same regardless of whether the input signals from the first and second photoreceptors PHT1 and PHT2 are high or low, that is, “1” and “1” or “ The output from this exclusive OR EXOR is low level “0” when it is “0” and “0”, and when either one is “1” and the other is “0”, the output from the exclusive OR EXOR is It is set to be a high level “1”.
[0030]
Therefore, when the heater main body 1 is in the air and when the light source LED stops emitting infrared light due to a failure, the output from the exclusive OR EXOR becomes low level, and this low level output signal is generated. In this case, the voltage comparison circuit CMP2 is set so that the heater HR is de-energized. The heater HR generates a signal to cut off the energization of the heater HR from the voltage comparison circuit CMP2 to the switch circuit PSW. Is to stop the operation.
[0031]
Further, when the heater body 1 is in water, the infrared light from the light source LED does not reach the second light receiving body PHT2, and only the rectangular wave signal output from the first light receiving body PHT1 is obtained. The input from the second photoreceptor PHT2 remains at a low level, and the other input becomes a rectangular wave signal having a cycle of the oscillation circuit OSC, and the output is also a rectangular waveform signal having this cycle. The rectangular wave signal is converted into a DC level by the rectifier circuit RC, and the voltage comparison circuit CMP2 is set so that the heater HR is energized when the DC level signal is generated. Therefore, in this state, the voltage comparison circuit CMP2 sends a signal for energizing the heater HR to the switch circuit to cause the heater HR to heat the water in the water tank.
[0032]
When water is heated by the heater HR as described above, the water temperature is detected by the water temperature sensing element (temperature resistance element) NTC, and the voltage of the water temperature sensing element NTC is set in advance (26 ° C.). The reference voltage Vref is compared with the other voltage comparison circuit CMP1, and the power switch circuit PSW is turned on / off by this compared voltage output to keep the water temperature at a predetermined temperature. It is the same. In the above embodiment, the heater body 1 is made of a glass tube. However, the heater body 1 may be formed of a transparent hard synthetic resin tube. In short, it is made of a translucent material. It may be formed from a material having excellent strength.
[0033]
【The invention's effect】
As described above, according to the heating device such as the water tank of the present invention, the heater main body having a light-transmitting cylindrical shape and the heater main body disposed in the heater main body are in the air. A light source that sometimes reflects toward the inside of the heater body on the surface of the heater body, while the heater body is in water, a light source that passes through the heater body, a light receiver that is disposed in the heater body and receives the reflected light, When the light receiving body receives reflected light, the heater is deenergized, and when the incident light is not transmitted through the heater body, the heater is energized. When the heater body is disposed in the water and the heater body is in water, the light from the light source passes through the heater body and is reflected on the water side without being reflected. Like a normal heating device, the water temperature in the water tank can be heated until it reaches a predetermined temperature, and of course, the heater body may unexpectedly come out of the water tank, or the water tank will be in an empty state due to the water tank falling over. In this case, the heater main body is present in the air, and the light from the light source that emits light in the heater main body is reflected by the low-density air toward the heater main body on the surface of the heater main body, The heater is immediately and reliably brought into a non-energized state by being received by the photoreceptor.
[0034]
As described above, since it is detected whether the heater body is in the air or in the water by utilizing the change in the refractive index of light between the air and the water, the switch circuit can be operated accurately. Because the heater is immediately de-energized when the heater body is in the air, the heater body is extremely reliable and safe without reaching a high temperature. If it is again put into the water tank, the heater is immediately energized and can be used for benefits.
[0035]
Further, the light receiving body includes a first light receiving body that always directly receives light from the light source and a second light receiving body that receives reflected light when entering the heater body from the light source. Whether the heater body is in the air or the water can be accurately detected by the second light receiver at the same time as detecting whether the light source has failed by the light receiver, and if the light source has failed, the heater Even if the main body is in the air, it can be used more safely by reliably eliminating malfunctions that are detected as being disposed in water.
[Brief description of the drawings]
FIG. 1 is a simplified longitudinal side view of a heating device,
FIG. 2 is a simplified perspective view of a printed circuit board portion;
FIG. 3 is a longitudinal front view of the light source and photoreceptor part,
FIG. 4 is a circuit configuration diagram of a heating device.
[Explanation of symbols]
1 Heater body 5 Shield plate
HR heater
LED light source
PHT1 first photoreceptor
PHT2 second photoreceptor
PSW power switch circuit
CMP1, CMP2 voltage comparison circuit
OSC oscillation circuit
ST1, ST2 Schmitt circuit
RC detector circuit
EXOR Exclusive OR
NTC Water temperature sensor

Claims (5)

  A light-transmitting cylindrical heater main body with a heater inside, and one surface of the heater main body that is disposed in the heater main body and reflects toward the heater main body when the heater main body is in the air A light source that passes through the heater body when the heater body is in water, a light receiver that is disposed in the heater body and receives the reflected light, and the heater is de-energized when the light receiver receives the reflected light. And a switch circuit for turning on the heater when the incident light is not transmitted through the heater body.   The aquarium or the like according to claim 1, further comprising: a first light receiving body that directly receives light from the light source; and a second light receiving body that receives reflected light when entering the heater main body from the light source. Heating device.   An oscillation circuit that generates an electrical signal by supplying a DC voltage from a power supply circuit, a light source that includes a light emitting element that is driven by a signal from the oscillation circuit, and a first transistor that includes a phototransistor that directly receives light emitted from the light source. A light receiving body, a second light receiving body comprising a phototransistor for receiving reflected light from the light source to the surface of the heater body, a switch circuit for energizing and de-energizing the heater, and the first and second light receiving bodies. The signals are compared to generate a signal that causes the switch circuit to energize the heater when the second light receiver is not receiving light even though the first light receiver is receiving light. 3. The comparison circuit according to claim 1, further comprising a comparison circuit that issues a signal for deenergizing the heater to the switch circuit when both are receiving light or not receiving light. Heating apparatus such as a water tank.   First and second Schmitt circuits for shaping the waveform of rectangular wave input signals from the first and second light receivers, respectively, between the first and second light receivers and the comparison circuit, and the first and second When the difference between the input signals from the Schmitt circuit is detected and the exclusive OR input to the comparison circuit is connected, the heater is turned off when the input signals from the first and second Schmitt circuits are the same. The heating device for a water tank or the like according to claim 3, wherein the comparison circuit is set to do so.   The heater body is made of a glass tube, and a transparent synthetic resin is filled in a part of the heater body, and the light source and the first and second light receiving bodies are embedded in the filled synthetic resin. A heating apparatus such as a water tank according to any one of claims 1 to 4.

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