JP3522656B2 - Microscope heating device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating device for a microscope which is mounted on a stage of a microscope and places a sample on a transparent heating plate for heating.

[0002]

2. Description of the Related Art In some cases, such as artificial insemination of animals, it is necessary to keep sperms and eggs (specimens) at a predetermined temperature and observe them with a microscope. As a device for satisfying this requirement, there is a microscope heating device. Japanese Patent Application No. 6-113540 (Patent No. 2835422)
No.), Japanese Patent Application No. 7-2714 (utility model registration No. 30168).
94) etc. This type of device is basically a transparent plate for heat generation, a transparent conductive film formed on the surface of the transparent plate for heat generation by a vapor deposition method, an electrode for energizing the transparent conductive film, and a transparent plate for heat generation. A protective transparent plate laminated at a predetermined distance from each other, an insulating transparent material such as silicon filled between the heat generating transparent plate and the protective transparent plate, a heat generating transparent plate and a protective transparent plate. It is composed of a temperature sensor arranged between them, a heat-generating transparent plate, and a housing for holding the outer edge of the protective transparent plate.

The microscope heating device is mounted on the stage of the microscope, the specimen placed on a slide glass or the like is placed on a protective transparent plate, and the transparent conductive film is energized to generate heat. Warm. Furthermore, the temperature is detected by a temperature sensor, and the temperature is adjusted by adjusting the power supply to the transparent conductive film based on the detected temperature. There are various types of this type of device depending on the type of microscope (inverted microscope, upright microscope, stereoscopic microscope) and the structure (shape) of the stage of the microscope.

[0004]

In the warming device mounted on the upright microscope, the focal length of the light source is extremely short. Therefore, the distance from the light source to the specimen must be as short as possible. It is required to make it thin. However, in the conventional microscope heating device, the diameter of the electric cord is large even if the housing is made thin, which hinders the thinning of the device. That is, the conventional electric cord has a core member as a center, a pair of power lines for energizing the electrodes around the core member, and a pair of signals connected to the temperature sensor, which are covered with an insulating outer cover. It is configured. Therefore, this electric cord has a substantially circular cross section, and there is a limit in reducing the diameter dimension. The thickness of the device cannot be made smaller than the diameter of the electric cord, which hinders the thinning of the device.

The present invention has been made in view of the above conventional problems, and an object of the present invention is to provide a heating device for a microscope which can be made thinner.

[0006]

In order to achieve this object, the invention of claim 1 is such that a transparent conductive film is formed on the surface of a transparent base plate, and a pair of electrodes for energizing the transparent conductive film. A heat-generating transparent plate, a protective transparent plate laminated at a predetermined distance on the heat-generating transparent plate, an insulating transparent material filled between the heat-generating transparent plate and the protective transparent plate, and A temperature sensor for detecting the temperature of the heat-generating transparent plate, a housing for holding the outer edges of the heat-generating transparent plate and the protective transparent plate, and a pair of power lines for supplying a current to the pair of electrodes. In the microscope heating device provided with an electric cord having a pair of signal cords consisting of a signal wire serving as a signal passage of the temperature sensor and an insulating covering material that coats the signal wire, the electric cord is , One signal code One power line is wound and is further covered with an outer cover, and the other signal cord is wound with the other power line and is further covered with an outer cover, and the signal cord is horizontal. The heating device for a microscope is characterized in that the heating device is inserted into the housing in a posture of being aligned in the direction.

According to a second aspect of the present invention, in the microscope heating device according to the first aspect, the pair of signal cords around which the power line is wound are covered with outer skins, and the outer skins are shaped like a figure eight. A heating device for a microscope, characterized in that they are connected to each other so as to form a cross section.

According to a third aspect of the present invention, in the microscope heating device according to the first or second aspect, the power line constituted by a large number of thin electrically conductive wires is wound around the outer peripheral portion of the covering material of the signal cord. A heating device for a microscope, which is characterized in that

A fourth aspect of the present invention is the heating device for a microscope according to the third aspect, wherein the electrically conductive wire is a copper wire.

According to a fifth aspect of the present invention, in the microscope heating apparatus according to any one of the first to fourth aspects, the electric cord is inserted from a hole formed on a side surface of the housing in a posture in which the signal cords are arranged in the horizontal direction. The heating device for a microscope is characterized in that

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A microscope heating device 40 according to a first embodiment will be described with reference to FIGS. 1 to 3.
Reference numeral 39 indicates a transparent plate for heat generation, and this transparent plate 39 for heat generation
Is a base plate 41 made of a rectangular transparent glass plate, a transparent conductive film 42 formed on the surface thereof, and the transparent conductive film 42.
It is composed of an electrode (not shown) for supplying electricity to. On the front surface side of the heat-generating transparent plate 39, a protective transparent plate 43 made of a rectangular transparent glass plate is laminated at a predetermined distance. Silicon 45 as an insulating transparent material is filled between the heat-generating transparent plate 39 and the protective transparent plate 43, and the heat-generating transparent plate 39 and the protective transparent plate 43.
Is fixed to the housing 46 by fixing silicon, and the outer edge portion thereof is held by the housing 46.

The length of the transparent heat generating plate 39 is larger than that of the protective transparent plate 43. In the laminated state, the exposed heat generating transparent plate 39 has an exposed portion 47 which does not overlap the protective transparent plate 43. The exposed portion 47 is not filled with silicon 45, and the transparent conductive film 42 is exposed. A temperature sensor 49 is arranged on the exposed portion 47 via a double-sided tape 51. The double-sided tape 51 is for fixing the temperature sensor 49 and electrically insulating the transparent conductive film 42. On the upper surface of the temperature sensor 49, a heat insulating member 44 made of a small piece of styrofoam is attached. Further, the temperature sensor 49 is provided at a position covered by the housing 46.

The microscope heating device 40 is mounted on a stage of a microscope, and a slide glass or the like on which a sample is placed is placed on a protective transparent plate 43. Then, the transparent conductive film 42 is energized to generate heat via the power line and the electrode provided on the transparent conductive film 42, and the sample is heated via the protective transparent plate 43 to keep the sample at a desired temperature. Observe. In the microscope heating device 40, the temperature is detected by the temperature sensor 49, the detection information is sent to the controller through this signal line, and the temperature is controlled by adjusting the energization of the electrodes based on the sent detection information. .

At this time, since the temperature sensor 49 is disposed on the exposed portion 47 not filled with the silicon 45 and the heat insulating member 44 is attached, the temperature of the transparent conductive film 42 can be accurately detected. . That is, in the conventional microscope heating device in which the temperature sensor is arranged in the portion filled with the silicon 45, the heat of the transparent conductive film is absorbed by the silicon and is not transferred straight to the temperature sensor. The temperature sensor detects that the temperature has not reached the predetermined temperature even though the temperature has reached the predetermined temperature.
Therefore, the microscope heating device 40 according to the first embodiment.
Then, the temperature sensor 49 is arranged on the exposed portion 47 as described above to prevent heat from being conducted to the silicon, and further, the heat insulating member 44 is provided to prevent the heat from escaping so that the temperature of the transparent conductive film 42 can be accurately measured. Enabled to detect.

Further, in this microscope heating device 40, since the temperature sensor 49 is arranged in the portion covered by the housing 46, for example, the petri dish 53 is used as the temperature sensor 4.
It is possible to prevent heat from being lost in the vicinity of 9 and prevent accurate temperature detection. That is, in the conventional microscope heating device, since the temperature sensor is provided at a position covered by the protective transparent plate, for example, a petri dish is placed on the protective transparent plate, and if this is just above the temperature sensor, the protection is performed. Heat is conducted to the petri dish through the substrate for use, and the temperature of the portion where the temperature sensor is arranged is lowered. Since the transparent conductive film is an extremely thin film, the amount of accumulated heat is extremely small, and when the heat is conducted to the petri dish, the temperature of that part rapidly drops in a short time, and the electrode is detected based on the temperature detection of the part where this temperature has dropped. When a current is applied to the transparent conductive film, an overshoot occurs in which the temperature of the central portion of the transparent conductive film becomes higher than the set temperature. In this microscope heating device 40, the temperature sensor 49 is covered by the housing 46 regardless of where the petri dish 53 is placed on the protective transparent plate. Can be prevented.

A microscope heating device 53 according to the second embodiment will be described with reference to FIG. Reference numeral 55 denotes a plastic housing, which has a box shape with an irregular octagonal shallow recess 58.
A round hole 57 is formed in the bottom of the recess 58. In the housing 55, a transparent plate 59 for heat generation, an insulating sheet 61 made of an electrically insulating material, an aluminum plate 63 as a heat conducting member, and an insulating sheet 6 having the same configuration as the insulating sheet 61.
5, a protective transparent plate 67 made of transparent glass is housed in this order, and the outer edge portion is held by the housing 55. All of these are irregular octagonal shapes so that they can be housed in the recesses 58 of the housing 55 almost exactly, and the insulating sheets 61, 65 corresponding to the round holes 57 of the housing 55.
Round holes 62, 66 on the aluminum plate 63 and round holes 6 on the aluminum plate 63.
4 are formed respectively.

The heat-generating transparent plate 59 is composed of a base plate 69 made of a transparent glass plate, a transparent conductive film 71 formed on the surface of the base plate 69, and a pair of electrodes 73, 73 for energizing the transparent conductive film 71. It is configured. Electrode 7
The power lines 3 and 73 are connected to a power line accommodated in an electric cord 75 attached to the housing 55, and the transparent conductive film 71 is energized through the power line and the electrodes 73 and 73 based on detection information of a temperature sensor (not shown). To be done. The microscope heating device 53 is mounted on the stage of the microscope, the specimen is placed on the protective transparent plate 67 and positioned so as to correspond to the round hole 57 of the housing 55, and the specimen is observed.

In the microscope heating device 53, when the transparent conductive film 71 generates heat, the heat is conducted and accumulated in the aluminum plate 63, and the heat is transmitted to the entire protective transparent plate 67. Therefore, the temperature of the protective transparent plate 67 is kept constant and the temperature distribution becomes uniform, so that the specimen heated to a predetermined temperature can be reliably observed. The heating device for microscope 53
Then, an aluminum plate is used as the heat conducting member,
The present invention is not limited to this, and the heat conductive member is a plate made of copper, silver or the like, a plate made of a plastic having a high heat conductivity, or a heat conductive silicon (product model number KE34- manufactured by Shin-Etsu Chemical Co., Ltd.).
93 or KE4560) or the like.

FIG. 5 shows a microscope heating device 77 according to the third embodiment. Reference numeral 79 denotes a plastic housing, which is formed in a substantially disc shape having a shallow circular recess 80, and a hole 81 is formed in the recess 80. In the housing 79, a heat-generating transparent plate 83 as a heat-generating plate, an insulating spacer 85 as an insulating member made of an electrically insulating material, and an aluminum plate 87 as a protective plate are housed in this order, and fixing silicon is used. The outer peripheral portion is held by the housing 79. In the center of the insulating spacer 85, a substantially square hole 86
However, a circular hole 88 is formed in the center of the aluminum plate 87. The surface of the aluminum plate 87 is anodized.

The heating transparent plate 83 is composed of a disk-shaped transparent glass plate and has a base plate 89 having a substantially square hole at the center, a transparent conductive film 91 formed on the surface of the base plate 89, and this transparent conductive plate. It is composed of a pair of electrodes 93, 93 for energizing the film 91. Electrodes 93, 9
3 is an electric cord 95 attached to the housing 79
Is connected to a power line accommodated in the transparent conductive film 91, and the transparent conductive film 91 is energized through the power line and the electrodes 93, 93 based on detection information from a temperature sensor (not shown). The microscope heating device 77 is mounted on the stage of the microscope, and the sample is placed on the stage and in the area within the round hole 88 of the aluminum plate 87 to observe the sample.

In this microscope heating device 77, when the transparent conductive film 91 generates heat, the heat is conducted and accumulated in the aluminum plate 87, and the heat is transferred to the entire protective transparent plate 77. Therefore, the temperature of the protective transparent plate 77 is kept constant, and the temperature distribution becomes uniform, so that the sample placed in the area inside the round hole 88 can be reliably heated to a predetermined temperature. Although the heating device 77 for microscope uses the transparent plate 83 for heat generation, since the sample is placed in the hole 88 for observation, the heat generation plate does not have to be transparent. The protective plate is not limited to aluminum, and may be made of metal such as copper or silver, or other plastic as long as the material has high thermal conductivity.

A microscope heating device 95 according to a fourth embodiment will be described with reference to FIGS. 6 and 7. Reference numeral 97 denotes a plastic housing, and the housing 9
7 is formed in a rectangular frame shape. This housing 9
A support portion 101 is formed so as to project inward of the hole 99 of No. 7. An electric cord 103 in which the power line and the signal line of the temperature sensor are housed is attached to the housing 97.

Reference numeral 105 denotes a heat-generating transparent plate. The heat-generating transparent plate 105 is a base plate 107 made of a rectangular transparent glass plate, a transparent conductive film 109 formed on the surface of the base plate 107, and this transparent conductive film 109 is energized. A pair of electrodes for
It is composed of 11, 111. Heat-generating transparent plate 1
A temperature sensor 106 is attached and arranged on the surface of 05 via a double-sided tape 108. Heat-generating transparent plate 10
A protective transparent plate 113 made of a transparent glass plate having a rectangular shape is provided on the front surface side of the mask 5, and the mask 112 is made of a paper having a rectangular frame shape.
Are stacked with a predetermined distance therebetween. Silicon 45 as an insulating transparent material is filled between the heat-generating transparent plate 105 and the protective transparent plate 113, and the heat-generating transparent plate 105 and the protective transparent plate 113 are fixed to the housing 97 by fixing silicon. Is fixed to the housing 97, and the outer edge portion thereof is held by the housing 97.

A round hole 115 is formed in the protective transparent plate 113, and the round hole 115 is provided at a position facing the temperature sensor 106. Reference numeral 117 indicates an aluminum disc serving as an outside air temperature transmitting member.
17 is sized to fit into the round hole 115.
As shown in FIG. 7, the aluminum disk 117 is made of silicon 1.
It is fixed to the round hole 115 by 16. The lower surface of the aluminum disc 117 contacts the temperature sensor 106, and the upper surface is exposed to the outside air.

The electrodes 111, 111 are connected to a power line accommodated in an electric cord 103 attached to the housing 97, and based on the detection information of the temperature sensor 106, the power line and the transparent conductive film via the electrodes 111, 111. 109 is energized. In the microscope heating device 95, a change in the outside air temperature is transmitted to the temperature sensor 106 via the aluminum disc 117. Therefore, the temperature sensor 106 detects the temperature according to the outside air temperature, and the transparent conductive film 109 is energized based on this detection information, and the temperature can be adjusted according to the outside air temperature. In the microscope heating device 95, an aluminum disk is used as the outside air temperature transmitting member, but the present invention is not limited to this, and the outside air temperature transmitting member may be made of a metal such as copper or silver having high heat conductivity, or a heat conducting member. Silicon or the like may be used. If heat conductive silicon is used, since it has plasticity, it can be easily attached to the temperature sensor 106.

A microscope heating device 119 according to the fifth embodiment will be described with reference to FIGS. Code 12
Reference numeral 0 denotes a plastic housing, and this housing 120 has a substantially disk shape having a circular shallow recess, and a large round hole 123 is formed in the center. The heat-generating transparent plate 125 is a base plate 12 made of a disk-shaped glass plate.
7. The transparent conductive film 1 formed on the surface of the base plate 127
29 and a pair of electrodes 13 for energizing the conductive film 129
1, 131. Heat-generating transparent plate 12
A ring-shaped heat insulating member 133 made of Styrofoam is attached to the lower surface of 5. A protective transparent plate 135 made of a disk-shaped glass plate is laminated on the heat generating transparent plate 125 with a predetermined distance therebetween, and the heat generating transparent plate 125 and the protective transparent plate 13 are stacked.
Silicon is filled in between 5 and 5, and a temperature sensor (not shown) is arranged.

A transparent plate 125 for heat generation and a transparent plate 135 for protection
Is accommodated in the recess 121 of the housing 120, is fixed by silicon, and the outer edge thereof is held by the housing 120. As shown in FIG. 9, the heat insulating member 133 is in contact with the bottom of the recess 121. An electric cord 137 accommodating the power line and the signal line of the temperature sensor is attached to the housing 120. The electrodes 131 and 131 are connected to a power line housed in an electric cord 137, the temperature sensor is connected to a signal line, and the transparent electric conduction is performed via the power line and the electrodes 131 and 131 based on the detection information of the temperature sensor. The membrane 129 is energized.

This microscope heating device 119 is a heat insulating member 1.
Since 33 is provided, it is possible to prevent heat from being transferred from the heat-generating transparent plate 125 to the housing 120 and being deprived of the heat, so that the temperature can be rapidly raised. That is,
Since the heat generating conductive film 129 is an extremely thin film, the amount of accumulated heat is extremely small, and when the heat generating transparent plate is in direct contact with the housing, heat is taken away and the temperature does not rise easily.
This can be prevented by providing the heat insulating member 133. In the microscope heating device 119, the heat insulating member is made of expanded polystyrene, but may be made of other plastic such as urethane resin. Further, the heat insulating member may be made of ceramic or the like.

A microscope heating device 139 according to a sixth embodiment will be described with reference to FIGS. Code 1
Reference numeral 41 denotes a plastic housing, and this housing 141 has a substantially square frame shape, and a supporting portion 143 protruding inward is formed. A projecting portion 145 is formed on the edge of the support portion 143.

Reference numeral 147 denotes a heat-generating transparent plate. The heat-generating transparent plate 147 includes a base plate 149 made of a rectangular glass plate, a transparent conductive film 151 and a transparent conductive film 151 formed on the surface of the base plate 149. It is composed of a pair of electrodes 153 and 153 for supplying electricity. On the back surface of the heat-generating transparent plate 147, a quadrangular frame-shaped heat insulating member 155 made of expanded polystyrene is attached. As shown in FIG. 11, the heat-generating transparent plate 147 includes a protective transparent plate 1 made of glass.
57 are laminated at a predetermined distance from each other to form a transparent plate 147 for heat generation.
Silicon 159 is filled between the protective transparent plate 157 and the protective transparent plate 157, and a temperature sensor (not shown) is arranged.

Transparent plate 147 for heat generation and transparent plate 157 for protection
Are housed in the housing 141, the back surface of the heat-generating transparent plate 147 is supported by the protruding portions 145 and fixed by silicon, and the outer edge portion thereof is held by the housing 141. There is a gap between the lower surface of the heat insulating member 155 and the upper surface of the support portion 143, and this gap constitutes the air layer 161. An electric cord 163 accommodating the power line and the signal line of the temperature sensor is attached to the housing 141. An electric cord 163 is provided on the electrodes 153 and 153.
The temperature sensor is connected to the signal line, and the transparent conductive film 151 is energized through the power line and the electrodes 153 and 153 based on the detection information of the temperature sensor.

The heating device 139 for the microscope is a heat insulating member 1.
Since 55 is provided, the same effect as that of the microscope heating device 119 is exhibited. In particular, the microscope heating device 139
Since the air layer 161 is formed between the heat insulating member 155 and the support portion 143 of the housing 141, a high heat insulating effect can be obtained. In the microscope heating device 139,
Although the heat insulating member is made of styrofoam, it may be made of other plastic such as urethane resin. Further, the heat insulating member may be made of ceramic or the like.

Claim 1 according to the drawings of FIGS.
The heating device for a microscope 165 will now be described in a seventh embodiment corresponding to claim 5. Microscope heating device 16
The configuration of the electric cord 167 provided in No. 5 will be described. Reference numerals 169 and 169 denote a pair of signal codes, and the signal codes 169 and 169 are formed by covering the signal line 171 with an electrically insulating coating material 173. Coating materials 173 and 173 for signal codes 169 and 169
Power lines 175 and 175, which are composed of a large number of thin copper wires, are wound around the outer peripheral portion of the. Power lines 175,1
The signal cords 169 and 169 around which 75 is wound are arranged in parallel and covered with the outer cover 177 in this state. The outer skin 177 has a cross-section shaped like an Arabic numeral "8" lying down.

As shown in FIG. 14, the electric cord 167 is
The signal cords 169 and 169 are inserted horizontally through the holes formed in the side surface of the housing 179, and the pair of power lines 175 and 175 are connected to the transparent plate 181 for heat generation.
Is connected to a pair of electrodes for energizing the transparent conductive film, and the pair of signal lines 171 and 171 is connected to a temperature sensor arranged on the transparent conductive film. A protective transparent plate 183 is laminated on the heat generating transparent plate 181 with a predetermined distance therebetween, and silicon as an insulating transparent material is filled between the heat generating transparent plate 181 and the protective transparent plate 183.

In the microscope heating device 165, the detection information of the temperature sensor is transmitted from the signal lines 171 and 171 to a controller (not shown), and the power lines 175 and 175 and the electrodes are energized to the transparent conductive film based on the detection information. To be done.
Then, the specimen 184 on the slide glass 182 is observed by the objective lens 185 of the upright microscope while being heated to a predetermined temperature. During this observation, it is necessary to focus the light emitted from the light source 186 at the position where the sample 184 is located. Since the electric cord 167 of the microscope heating device 165 has the above-described structure and is attached to the housing 179 in the above-described posture, the height dimension can be reduced. Therefore, the microscope heating device 165 can be made considerably thinner than when using a conventional electric cord. Therefore, even if the focal length of the light source 186 is considerably short, it is possible to focus on the position of the specimen 184.

The power lines 175 of the electric cord 167 are
When connecting 175 to the electrode, the power line 1 wound around the signal cords 169 and 169 as shown in FIG.
Remove 75 and 175, twist and solder to the electrode.

Although the embodiment of the present invention has been described in detail above, the specific configuration is not limited to this embodiment, and there are design changes and the like without departing from the scope of the present invention. Also included in the present invention.

[0038]

As described above, according to the first to fifth aspects of the present invention, the height dimension of the electric cord can be reduced, and when the conventional electric cord is used as the microscope heating device. It can be made considerably thinner than. Therefore, even if the focal length of the light source of the upright microscope is considerably short, it is possible to focus on the position of the sample.

[Brief description of drawings]

FIG. 1 is a plan view of a microscope heating device according to a first embodiment.

FIG. 2 is a sectional view taken along line AA of FIG.

FIG. 3 is a partially enlarged view of FIG.

FIG. 4 is an exploded perspective view of a microscope heating device according to a second embodiment.

FIG. 5 is an exploded perspective view of a microscope heating device according to a third embodiment.

FIG. 6 is an exploded perspective view of a microscope heating device according to a fourth embodiment.

FIG. 7 is a partially enlarged cross-sectional view of a microscope heating device according to a fourth embodiment.

FIG. 8 is an exploded perspective view of a microscope heating device according to a fifth embodiment.

FIG. 9 is a cross-sectional view of a microscope heating device according to a fifth embodiment.

FIG. 10 is an exploded perspective view of a microscope heating device according to a sixth embodiment.

FIG. 11 is a sectional view of a microscope heating device according to a sixth embodiment.

FIG. 12 is a perspective view showing an internal structure of an electric cord installed in a microscope heating device according to a seventh embodiment.

FIG. 13 is a perspective view showing an internal structure in a state in which a power line of an electric cord mounted in the microscope heating device according to the seventh embodiment is twisted.

FIG. 14 is a front view for explaining a usage state of the microscope heating device according to the seventh embodiment.

[Explanation of symbols]

40 ... Microscope heating device 41 ... Base plate 43 ... Protective transparent plate 42 ... Transparent conductive film 45 ... Silicon 46 ... Housing
47 ... Exposed part 49 ... Temperature sensor 53 ... Microscope warming device 55 ... Housing 59 ... Exothermic transparent plate 63 ... Aluminum plate 67 ... Protective transparent plate 69 ... Base plate 71 ... Transparent conductive film 73 ... Electrode 77 ... Microscope Heating device 79 ... Housing 83 ... Exothermic transparent plate 87 ... Aluminum plate 89 ... Base plate 91 ... Transparent conductive film 93 ... Electrode 95 ... Microscope heating device 97 ... Housing 105 ... Exothermic transparent plate 106 ... Temperature sensor 107 ... Base plate 109 ... Transparent conductive film 111 ... Electrode 113 ... Protective transparent plate 116 ... Silicon 117 ... Aluminum disc 119 ... Microscope heating device 120 ... Housing 125
... Transparent plate 127 for heat generation ... Base plate 129 ... Transparent conductive film 133 ... Insulating sheet 135 ... Transparent plate 139 for protection ... Heating device for microscope 141 ... Housing 147
Heat-generating transparent plate 149 ... Base plate 151 ... Transparent conductive film 153 ... Electrode 155 ... Insulating member 157 ... Protective transparent plate 159 ... Silicon 161 ... Air layer 165 ... Microscope warming device 167 ... Electrical cord 169
... Signal code 171 ... Signal line 173 ... Coating material 175 ... Power line 17
7 ... Outer skin 179 ... Housing 181 ... Transparent plate for heat generation 183 ... Transparent plate for protection

─────────────────────────────────────────────────── ─── Continuation of the front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) G02B 21/00-21/36

Claims (5)

(57) [Claims] 1. A heat-generating transparent plate having a transparent conductive film formed on the surface of a transparent base plate and having a pair of electrodes for energizing the transparent conductive film, and a predetermined distance from the heat-generating transparent plate. A laminated protective transparent plate, an insulating transparent material filled between the heat generating transparent plate and the protective transparent plate, and a temperature sensor for detecting the temperature of the heat generating transparent plate,
A housing that holds the outer edge portions of the transparent plate for heat generation and the transparent plate for protection, a pair of power lines for supplying an electric current to the pair of electrodes, and a signal line serving as a passage for a signal of the temperature sensor. In a microscope heating device provided with an electric cord having a pair of signal cords composed of an insulating coating material for covering the signal lines, the electric cord is one power cord wound around one of the signal cords, The one covered with the outer cover, the other power cord wound on the other signal cord, and the other covered with the outer cover are coupled to each other, and the signal cords are inserted into the housing in a posture in which they are aligned in the horizontal direction. A heating device for a microscope, which is characterized in that 2. The warming device for a microscope according to claim 1, wherein the pair of signal cords around which the power line is wound are covered with an outer skin, and the outer skins form an 8-shaped cross section. A heating device for a microscope, characterized in that they are connected to each other. 3. The heating device for a microscope according to claim 1, wherein a power line composed of a large number of thin conductive wires is wound around the outer periphery of the covering material of the signal cord. Characteristic heating device for microscopes. 4. The heating device for a microscope according to claim 3, wherein the electrically conductive wire is a copper wire. 5. The warming device for a microscope according to any one of claims 1 to 4, wherein the electric cord is inserted through a hole formed on a side surface of the housing in a posture in which the signal cords are arranged in a horizontal direction. Characteristic heating device for microscopes.